The Issue The issue is whether Respondent Department of Environmental Protection (DEP) may issue to Respondent Republic Services of Florida, L.P. (Republic), permits to construct and operate a Class III landfill, pursuant to Permit Numbers 266830-003-SC/01 and 266830-004-SO/01, as modified as set forth below.
Findings Of Fact Background On June 30, 2009, Republic filed with DEP an application for a permit to construct and operate a Class I landfill (Application). In response to DEP's request for additional information dated July 30, 2009 (RAI), Republic filed a response dated September 14, 2009 (RRAI), upon receipt of which, DEP deemed the Application to be complete. References to the Application typically include the Application, RRAI, and other materials, such as reports, plans, and drawings, that are part of the Application, as well as three subsequent modifications, which are detailed below. Republic revised several reports, plans, and drawings in the RRAI; references to these items, such as the Engineering Report and Operation Plan, are to the versions contained in the RRAI. On November 13, 2009, DEP filed its intent to issue construction permit #266830- 003-SC/01 (Construction Permit) and intent to issue operation permit #266830-004-SO/01 (Operation Permit; collectively, the Permit). Republic Services, Inc. and its affiliates constitute the second largest waste-management operator group in the United States. Their market capitalization is just over $11 billion. The capitalization of the affiliate formed to operate the subject landfill is doubtlessly less than $11 billion, as the record does not suggest that any significant part of the overall capitalization of Republic Services, Inc., and its affiliates would be at risk in the operation of the proposed landfill. Republic presently owns and operates a Class III landfill in the City of Bartow, Polk County, known as the Cedar Trail Landfill. The oldest part of this landfill is an unlined Class III landfill of 52.5 acres in the center of the property owned by Republic. Immediately west of this unlined landfill is a 30.7-acre lined Class III landfill, which comprises cells 1-4. The Cedar Trail Landfill is located at 2500 West State Road 60, about three miles west northwest of the intersection of State Road 60 and State Road 98, which marks the center of Bartow. The landfill is immediately west of E.F. Griffin Road. Petitioners Frost live on E.F. Griffin Road, about one mile north of the Cedar Trail Landfill. Petitioner Highland Lakes Estates Homeowner's Association serves a residential subdivision known as Highland Lakes Estates. Highland Lakes Estates occupies a notch at the southeast corner of Republic's property. Aerial photographs reveal the changing land use of the land on which Cedar Trail Landfill is situated. Fifty years ago, the land was vacant with indications of agricultural uses. At the site of the proposed landfill were mostly citrus groves on the west side and some rangeland or vacant land on the east side. Ten years later, a large area immediately northeast of the subject land reveals the effects of strip mining for phosphate. Three years later, in 1971, the mined area had greatly expanded to encompass all or nearly all of the subject site and much of the surrounding area, including the western half of what would become Highland Lakes Estates. By 1980, the pits had been refilled and active mining had ceased, and the streets had been constructed for what is now known as Highland Lakes Estates. By 1993, about three dozen homes had been built in this residential, large-lot subdivision. 9. The Cedar Trail Landfill was constructed in the early 1990s as an unlined construction and demolition debris landfill. Now designated an approved landfill for Class III waste, this facility accepts such waste as is defined by Florida Administrative Code Rule 62-701.200(14) (2010), which includes construction and demolition debris, yard trash, processed tires, asbestos, carpet, paper, glass, furniture (but not white goods), plastic, and other materials not expected to produce leachate that presents a risk to the public health or environment. A zoning/land use map reveals that the land for which the proposed landfill is proposed is designated "sewage/borrow pits/spray fields." Highland Lakes Estates occupies land that is designated single-family residential with a density of one dwelling unit on up to 2.49 acres. The Cedar Trail Landfill has been the subject of three recent environmental resource permits (ERPs). Appendix R to the Application is an individual ERP issued in April 2009, and Appendix R to the RRAI is a conceptual ERP issued in March 2005. The April 2009 ERP mentions that the entire stormwater project was conceptually approved by an ERP issued on September 10, 2008, but this ERP is not part of the record. In any event, these ERPs approve the construction of a comprehensive stormwater or surface water management system for the entire Republic property. In particular, the April 2009 ERP permits the construction of a borrow pit at the southeast corner of the Republic property and a modification of the perimeter ditch/wet retention system. The April 2009 ERP states that the permitted stormwater management system will provide total onsite retention for runoff from the 100-year, 24-hour storm. The April 2009 ERP requires 2.8 acres of compensation for 2.8 acres of encroachment in the 100-year floodplain. Specific Condition 14 prohibits excavation of the borrow pits to a clay confining layer or limestone bedrock layer. Specific Condition 20 prohibits the mixing of leachate with stormwater and provides that, if leachate enters stormwater, the stormwater becomes leachate. Presumably reflecting this permitting activity, Application Drawing 4, as revised in the RRAI, is the site plan, including the unlined Class III landfill, the four-cell lined Class III landfill immediately to the west of the unlined landfill, and the eight cells proposed to accept Class I waste. These eight cells are immediately south of the four cells of the lined Class III landfill. The two northernmost of these eight cells abut, on their east boundary, the unlined Class III landfill. The remaining six cells abut, on their east boundary, an 800-foot wide borrow pit, which lies between these cells and Highland Lakes Estates. Immediately north of Highland Lake Estates is a second borrow pit, and west of this borrow pit is the unlined Class III landfill. The other major feature on the site plan is a third borrow pit running, from west to east, along the north border of the lined Class III cells, the unlined Class III landfill, and the second borrow pit. Bearing no signs of ambitious reclamation activity, the backfilled mining cuts host large water storage areas and, as described in the application for the March 2005 ERP, wetlands of "very poor quality." The backfilled soils are best described as complex surficial soils, consisting mostly of fine sands with varying amounts of organics, silts, and clays. Geotechnical investigations of the Cedar Trail Landfill suggest that mining depths, although variable, probably averaged 40 feet. Petitioners and Intervenor are substantially affected by the Permit and the construction and operation of the proposed landfill, which will stand nearly 200 feet above grade and will be the focus of substantial activity six days per week during its years of operation. Like Petitioners, Intervenor owns land in the immediate vicinity of the Cedar Trail Landfill, which is in the jurisdiction of Intervenor, and Intervenor's various municipal operations are much affected by whether the proposed Class I landfill is permitted. Among other things, Intervenor has agreed to accept untreated leachate from the proposed landfill. Petitioners Frost built their home in 1980 or 1981. During the hours of operation of the existing landfill, Petitioners Frost constantly hear the beeping noise of heavy- duty equipment, presumably a safety device when the equipment is moved. Over a dozen lots in Highland Lakes Estates abut the property line of the Cedar Trail Landfill, and the closest residence is about 1000 feet from the nearest proposed Class I cell. At present, the existing landfill subjects the Highland Lakes Estates to constant noise during operating hours and a coating of dust inside their homes. Several residents of Highland Lakes Estates testified. Hard-working people, some of whom are now retired, these residents decided to purchase homes in Highland Lakes Estates because it was a sunny, healthy place to live. Over time, most of these residents, by varying degrees, have come to accept the fact of the Class III operations at Cedar Trail Landfill, but they object to the substantial intensification of land use that will result from a regional Class I landfill. One resident testified that she finds in her pool dirt that has escaped from the existing landfill, and she has become concerned about her grandchildren coming over to swim. Another resident testified that he only began closing his windows five or six years ago when the noise levels at the existing landfill increased; he eventually had to install a window air- conditioner. The same resident testified that the green herons and snowy egrets that he used to see around his house have not returned for five years, and his wife, who has health problems, including respiratory distress, would suffer from the expanded landfill operations. Application, RRAI, and Permit, Including Modifications The Permit incorporates the Application, including the RRAI, Engineering Report, Operation Plan, and drawings. Thus, all of the documents are part of the Permit. In the Application, Republic proposes to convert cells 5-8, which are not yet constructed, from a Class III to a Class I landfill and add four new cells adjacent to the unused cells. The unfilled portion of Cells 1-4 would continue to receive only Class III waste. Pursuant to Florida Administrative Code Rule 62-701.200(13) (2010), Class I waste is all solid waste, other than hazardous waste, that is not otherwise prohibited by rule. The Application states that the proposed landfill will serve communities within 100 miles. The service area of this regional landfill will thus extend in central Florida from Marion to Osceola counties, along the Gulf Coast from Pasco to Lee counties, and along the Atlantic Coast from Volusia to Martin counties. As stated in the Application, this service area is populated by 9.7 million persons, who would daily account for 3000 tons of waste at the Cedar Trail Landfill. Initially, according to the Engineering Report, the proposed landfill will receive 1600 tons per day of Class I waste, but, once the existing Class III cells are filled, the proposed landfill will receive 1600 tons per day of Class I waste plus the 1400 tons per day of the Class III waste that is currently going into the existing landfill. As revised by the RRAI, the life expectancy of the proposed landfill is seven years. The Application states that Republic will employ an attendant, a trained operator, and 3-5 spotters at the landfill. The Application reports that the landfill would operate Monday through Saturday from 7:00 a.m. to 6:00 p.m. and that the working face would be covered daily. The Application reports that Republic would install seven new detection wells and use 17 existing wells for monitoring groundwater and would use two existing staff gauges for monitoring surface water, evidently at a single location, as discussed in the next paragraph. 23. Application Appendix V is the Water Monitoring Plan. Appendix V states that surface water will be monitored every time that the stormwater pond for the leachate storage area discharges offsite, but not more frequently than weekly. Application Drawing 4, as revised in the RRAI, shows that the sole surface water monitoring location is close to the leachate storage tanks, which are described below. 23. Appendix V also requires leachate monitoring, "at least annually," for five field parameters--specific conductivity, pH, dissolved oxygen, colors, and sheens; eight laboratory parameters--including chloride, mercury, and total dissolved solids; and the parameters listed in 40 CFS Part 258, Appendix II, which includes a comprehensive list of volatile organic compounds; persistent organic pollutants, including 2,3,7,8-TCDD (a major dioxin) and Dibenzofuran; and metals, including lead and chromium. Fourteen days prior to all sampling events, Republic is required to notify DEP, so that it may obtain split samples for its own analysis. Republic is required to report the results of the groundwater monitoring quarterly and to analyze the groundwater data in a technical report filed with DEP every two years. Appendix V also requires monitoring for odors and combustible gases, mostly methane. Republic will monitor combustible gas quarterly at various ambient locations, such as the office buildings and to monitor combustible gas quarterly in the soil down to the seasonal high water table. The purpose of this monitoring is to determine combustible gas concentrations and, if they exceed 25%, take "all necessary steps to ensure protection of human health." Some confusion in the Application arises as to the issue of whether the Cedar Trails Landfill will be subject to, or voluntarily implement, the more elaborate provisions applicable to a landfill covered under Title V of the federal Clean Air Act, as amended in 1990. Regulated emissions for a new source might include particulate matter, sulphur dioxide, nitrogen oxides, volatile organic compounds (VOCs), and specified hazardous air pollutants. Appendix V states that the landfill will become a Title V landfill once permitted to receive Class I waste, and, at that time, it will be subject to a "more comprehensive system of landfill gas collection and monitoring." Appendix V assures that these items "will be addressed in separate documentation from this monitoring plan"--and, apparently, separate from the present record. By contrast, the Operation Plan concedes only that, based on the nature of Class I waste and the design capacity of the proposed landfill, Cedar Trail Landfill "may" become a Title V facility. The Operation Plan states: "If the regulatory thresholds at [Cedar Trail Landfill] are met [under Title V] requiring an active gas collection and control system (GCCS), [Cedar Trail Landfill] will submit as required the GCCS design plans for approval and install an active gas extraction system within the regulatory timeframes specified by Title 40, Code of Federal Regulations, Part 60, Subpart WWW." More specific provisions in the Operation Plan identify best management practices to prevent objectionable odors. Four practices are identified, including an "active gas collection and extraction system." On the DEP form application, which is a cover sheet to the more elaborate application materials, Republic checked boxes indicating that the landfill would use active gas controls with gas flaring and gas recovery, which is probably what is meant by an "active gas collection and extraction system." The Application provides that the landfill liner would be double composite; the leachate collections system would consist of collection pipes, geonets, and a sand layer; the leachate would be stored in tanks; some of the leachate would be recirculated as spray on the working face; and the remainder of the leachate would be stored onsite and periodically transferred to a wastewater treatment center for treatment. The Engineering Report states that the waste disposal footprint will not be located where geological formations or other subsurface features will not provide support for the waste. The Engineering Report identifies appendices addressing the slope-stability analysis and foundation analysis and relies on a March 12, 1997, report by Ardaman & Associates, Inc. (Ardaman Report), January 23, 2004, report by Golder Associates, Inc. (Golder Report), and June 26, 2009, report by Hanecki Consulting Engineers, Inc. (Hanecki Report). These items are discussed in greater detail below in connection with the sinkhole issue. The Engineering Report assures that the waste disposal footprint will not be within 500 feet of an existing or approved potable water well, nor will it be within 1000 feet of an existing or approved potable water well serving a community water supply. The Engineering Report adds that the minimum horizontal distance between waste deposits and the property line is 100 feet. The Engineering Report assures that the landfill footprint will not be in a dewatered pit, as the installation elevations are at least 2-3 feet higher than the seasonal high water table. The Engineering Report acknowledges that a small part of the eastern end of the four southernmost cells lies within the 100-year floodplain, as depicted by the Flood Insurance Rate Map effective December 29, 2000, and as shown in Application Appendix A, Drawing 1. Claiming that the relevant map was not revised in 2000, the Engineering Report asserts that the last update to the FIRM map was in 1975, and the depicted floodplain was filled during the mine reclamation process. The Engineering Report notes that the floodplain concerns were addressed in the April 2009 ERP. 34. The Engineering Report discloses two enforcement actions against Republic at the Cedar Trail Landfill. In a letter dated October 19, 2001, DEP warned Republic about noncompliant items at the site, and, in a notice of noncompliance dated January 30, 2006, DEP warned Republic not to use a new cell prior to construction certification of the cell's stormwater system. Both matters were reportedly resolved, and Republic has not been the subject of other enforcement actions for the Cedar Trails Landfill. At DEP's urging, the RRAI elaborates on enforcement actions against Republic or, evidently, Republic affiliates at a variety of Florida facilities, not just landfills. The additional information reveals that DEP imposed a fine of $61,300 for the October 2001 violations, which included disposing of unacceptable waste, storing an excessive number of tires and exceeding groundwater standards without notifying DEP, and a fine of $1000 for the January 2006 notice of noncompliance. The other enforcement actions against Republic or affiliates concerning landfills involved consent orders about the Nine Mile Road Landfill (Seaboard Waste): in February 2003, DEP imposed a fine of $13,000 in settlement of charges that employees were not removing all unacceptable waste from the site and, in November 2005, DEP imposed a $285 fine for a failure to submit required stormwater monitoring reports. There were many other enforcement actions, generally resulting in modest fines, but they involved hauling facilities, transfer stations, and materials recovery facilities, not landfills. The Engineering Report states that the proposed landfill is within six miles of, but greater than 10,000 feet from, the Bartow Municipal Airport. Airport safety is addressed in more detail below. The Engineering Report describes in detail the double composite liner system, which uses materials whose physical, chemical, and mechanical properties prevent failure due to contact with Class I waste and leachate, climactic conditions, installation stress, and other applied stresses and hydraulic pressures. The Engineering Report performs no contingency sinkhole analysis. The report does not suggest that the liner system could withstand the stresses and pressures resulting from any size sinkhole, so the necessary inference is that the liner will fail if any sinkhole forms directly beneath it. The Engineering Report states that waste placement will remain within the lined containment berm. The Engineering Report describes in detail the double composite liner system for use at the proposed landfill. The primary liner system and secondary liner system each comprises three layers with the top layer consisting of a composite drainage net, the middle layer consisting of a high-density polyethylene geomembrane with a minimum average thickness of 60 ml, and the bottom layer consisting of a geosynthetic clay liner with a maximum hydraulic conductivity of 5 x 10-9 cm/second. The Engineering Report describes in detail the leachate collection and removal system, which, sitting atop the primary liner, includes a 24-inch thick sand drainage layer with a minimum hydraulic conductivity of 1 x 10-3 cm/second, a composite drainage net, and a single perforated 8-inch diameter lateral pipe in each cell. The collection lateral pipes will gravity drain to the east to a header pipe that gravity drains to the primary leachate collection pump stations--one station for the four converted cells and one station for the four new cells. A smaller leachate collection and removal system will handle the leachate that penetrates to the leak detection layer by routing it to a secondary leachate collection pump station. Based on calculations derived from the HELP groundwater model, the leachate collection and removal system is designed to prevent leachate head from exceeding the thickness of the composite drainage net (about 1 cm) over the secondary geomembrane and from exceeding one foot over the primary geomembrane. According to the Engineering Report, flow meters will be installed at each of the pump stations to allow daily readings of the amount of leachate being pumped. At one foot of head over the primary liner, the Engineering Report expects just over three gallons per day collected at each secondary leachate collection pump station--significantly less than the leakage rate typical of a double liner system without a geosynthetic clay liner beneath the primary liner. However, the Engineering Report provides a standard action leakage rate of 100 gallons/acre/day, meaning that Republic is required to report to DEP liner leakage only when this leakage rate is attained. The pump stations will transmit the leachate to one of two above-ground, 150,000-gallon storage tanks. From these tanks, most of the leachate will be transported to an offsite location for treatment. However, up to 12,000 gallons per day of the untreated leachate will be recirculated to be sprayed on the working faces of the landfill. This is to control dust and possibly to assist with the degradation of the waste. The Engineering Report states that the Cedar Trail Landfill implements a facility-wide water quality monitoring plan. Upon completion of the pump stations for the eight cells that are the subject of the Application, Republic will expand its leachate sampling program to include annual sampling of the leachate collected in the primary and secondary leachate collection pump stations. The groundwater monitoring wells would be installed as closely as possible to the outer edge of the roadway that, with a stormwater ditch, will run the perimeter of the proposed Class I landfill. In the revised Engineering Report contained in the RRAI, Republic proposes a surface water discharge point in the stormwater pond located near the leachate storage tanks. The Engineering Report adds that Republic will continue to comply with the following prohibitions: No waste will be knowingly burned on site; Hazardous waste will not knowingly be accepted; PCB contaminated waste will not knowingly be accepted; Untreated biomedical waste will not knowingly be accepted. Please note that treated biomedical waste may be accepted at [Cedar Trail Landfill]'s Class I Landfill provided that the waste containers are marked "Treated Biomedical Waste.;" No waste disposal at the proposed Class I Landfill will occur within 3,000 feet of a Class I surface water body; [Cedar Trails Landfill] will not knowingly accept liquid waste within containers, excluding leachate and gas condensate derived from solid waste disposal operations. [Cedar Trails Landfill] will comply with the requirements of Rule 62- 701.300(10), FAC regarding the handling of liquid wastes; Neither oily waste nor commingled oily waste will knowingly be accepted; and Lead-acid batteries, used oil, white goods, and whole-waste tires will not knowingly be disposed of in the Class I waste disposal system. The Joint Stipulation to Permit Modification, identified above, adds four items to this list of operational prohibitions: i. Garbage will not be knowingly accepted; Household Waste, except waste from residential sources generated as Class III waste, will not be knowingly accepted; Animal carcasses will not be knowingly accepted; and Aluminum dross will not be knowingly accepted. Capitalized terms are generally defined in the Florida Administrative Code. Florida Administrative Code Rule 62-701.200(39) defines "Garbage" as " all kitchen and table food waste, and animal or vegetative waste that is attendant with or results from the storage, preparation, cooking, or handling of food materials." Application Appendix H is the Operation Plan, which also identifies the types of wastes to be permitted at the proposed landfill. Section 3(b) of the Operation Plan authorizes the proposed landfill to accept: Commercial waste Ash residue Incinerator by-pass waste Construction and demolition debris, including from a residence Treated biomedical waste Agricultural waste Industrial waste Yard trash, including from a residence Sewage sludge Industrial sludge Water/air treatment sludges Waste tires De minimis amounts of non-hazardous waste from incidental residential sources Section 5 of the Operation Plan provides, in relevant part: [Cedar Trail Landfill] will accept waste included in any of the waste categories identified under Section 3(b) of this Operation Plan[, but] will . . . NOT knowingly accept any hazardous waste, untreated biomedical waste, liquid waste (including paint), explosive waste, toxic waste, or radioactive waste for disposal at the [Cedar Trail Landfill.] Unacceptable types of refuse are listed below and will not be knowingly accepted for disposal. --Hazardous waste --Explosive waste --Radioactive waste --Drums that have not been opened and Emptied --Refrigerators, freezers, air Conditioners (white goods) --Any toxic or hazardous materials, i.e. batteries, solvents, oil, etc. --Automobiles or parts that contain fuel, lubricants, or coolants --Untreated Biomedical waste The original Application prohibited the acceptance of septic tank pumpage, but the application form accompanying the original Application indicated that the proposed landfill would accept industrial sludge and domestic sludge. After modification by the RRAI, the prohibition against accepting septic tank pumpage was deleted, and the Operating Plan added, among acceptable wastes, sewage sludge, industrial sludge, and water- and air-treatment sludge. Florida Administrative Code Rule 62-701.200(101) (2001) defines "sludge" to include solid waste pollution control residual from an industrial or domestic wastewater treatment plant, water supply treatment plant, air pollution control facility, septic tank, grease trap, portable toilet, or other source generating a waste with similar characteristics. Florida Administrative Code 62-701.200(64) (2001) defines "liquid waste" as any waste with free liquids, according to the "Paint Filler Liquids Test." As modified by the Joint Stipulation to Permit Modification, Section 5 of the Operation Plan was amended to add the following items to unacceptable types of refuse that will not be knowingly accepted for disposal: --Garbage --Household Waste, except waste from residential sources generated as Class III waste --Animal carcasses --Aluminum dross At the hearing, Republic and DEP agreed to an additional condition to the Operation Plan that unacceptable waste would include Garbage contained in commercial, industrial or agricultural waste. According to the Operation Plan, the initial waste screening occurs at the gate house where the attendant interviews the driver and inspects the incoming waste load. If the attendant sees more than a negligible amount of unauthorized wastes, he will reject the load and will contact the hauler to identify the source of the waste. Additionally, Republic will notify DEP if anyone tries to dispose of hazardous waste at the proposed landfill. As modified by the Joint Stipulation to Permit Modification, the Operation Plan was amended to provide a new paragraph between the paragraph addressing the initial waste screening at the gate house and, as discussed below, the second screening at the working face. The new paragraph provides: Any malodorous waste will be covered with mulch and/or additional soil or other approved cover materials to control odors promptly, within one (1) hour from the time of unloading, except in the event of exigent circumstances, such as extreme weather. Cedar Trail Landfill will promptly cover any sludge deposited on the landfill working face within one (1) hour from the time of the unloading, except in the event of exigent circumstances, such as extreme weather. At the hearing, Republic and DEP agreed to an additional condition to the Operation Plan, which would prohibit Republic from accepting malodorous waste or sludge that, due to exigent circumstances, it would not be able to cover within one hour from the time of unloading. If the load passes the initial waste screening, it will proceed to the working face of the landfill, according to the Operation Plan. At least one spotter will be stationed at the working face at all times that the landfill receives waste. Her job will be to detect unauthorized wastes. Republic is to assure that it has a sufficient number of spotters to find and remove unauthorized waste prior to compaction. The Operation Plan allows the spotter to work from ground level or the cab of a compactor. If the operator of a piece of heavy equipment is trained as a spotter, she may also serve as a spotter. During periods of higher waste traffic, the equipment operator will, according to the Operation Plan, "likely" need the assistance of another operator or spotter to screen the higher waste volumes. When finding unauthorized wastes in manageable volumes, the spotter or operator will remove these wastes by hand and place them into nearby containers for removal to an appropriate facility. The third waste screen occurs as the equipment operator spreads the waste, pursuant to the Operation Plan. The equipment operator is required to place any unacceptable observed wastes into containers, which will be located "within the lined area." These wastes will also be removed to an appropriate facility. In the RAI, DEP questioned the proximity of the containers to the working face, as the lined area consists of 72 acres, but, in the RRAI, Republic ignored the comment, restating only that the containers would not be located outside the lined area. The Operation Plan specifies a filling sequence. Republic will assure that the first layer of waste placed above the liner in each cell will be a minimum of four feet in compacted thickness and will be free of rigid objects that could damage the liner or leachate collection and removal system. Republic will maintain the working face to minimize the amount of exposed waste and initial cover necessary at the end of each day. The filling sequence will proceed until the permitted final grade elevations have been reached, less three feet for the final cover. The Operation Plan states that the initial cover at the Class I landfill will consist of a six-inch layer of soil that is transferred from onsite borrow pits or offsite sources. This soil will be compacted and placed on top of the waste by the end of each work day. At Republic's option, subject to DEP's approval, it may use a spray-on or tarpaulin cover, instead of a soil cover. The Operation Plan requires Republic to apply at least one foot of intermediate cover within seven days of cell completion, if additional waste will not be deposited within 180 days of cell completion. Republic may remove all or part of this intermediate cover before placing additional waste or the final cover. Through the placement of initial, daily, and intermediate cover, Republic will minimize the occurrence of moisture infiltration, fires, odors, blowing litter, and animals and other disease vectors. 59. The Operation Plan requires Republic to control litter primarily by daily waste compaction and cover. However, at least daily, if needed, employees will collect litter along the entrance and access roads and around the working face. Complaints about litter must be logged. In addition to the inspections detailed above, the Operation Plan establishes a random load-checking program to detect unauthorized wastes. Each week, Republic employees will examine at least three random loads of solid waste by requiring drivers to discharge their loads at a designated location within the landfill where the employees may undertake a detailed inspection. All random inspections will be logged. Notwithstanding the daily limit of 12,000 gallons per day, the Operation Plan prohibits Republic from spraying leachate during rain events. To apply the recirculated leachate, the lead operator will drive the leachate tanker truck on the working face, so that it can spray leachate over waste as it is being compacted, but after it has been screened by spotters. The spraying will be done to avoid causing leachate to pond atop the waste and will not be done within 50 feet of an outside slope. No restrictions apply to wind conditions. The Operation Plan states that, if the annual sampling of leachate water quality at the two pump stations reveals a contaminant in excess of the permissible limits listed in 40 CFR Part 261.24, Republic will start monthly sampling and notify DEP in writing. Also, the Cedar Trail Landfill will maintain a recording rain gauge. The Operation Plan requires Republic employees to conduct daily surveys for objectionable odors and take immediate corrective action, if odors are found at the property line. As modified by the Joint Stipulation to Permit Modification, this portion of the Operation Plan was amended to add two odor- remediation actions and another form of odor inspection. The two additional actions to prevent odors are to 1) provide additional cover using mulch, additional soil, or other approved cover material and 2) use odor masking or neutralizing agents. The new inspection provision states: Internal inspection will be performed on a weekly basis by a properly trained odor ranger or equivalently trained person. Such individual will tour the facility, property boundary, and the subdivision of Highland Lakes Estates . . . to identify any odors leaving the Landfill's property boundaries. The results of each weekly inspection will be document, and any odors identified will be mitigated. Another new provision from the Joint Stipulation for Permit Modification applies to the handling of sludge. As amended, the Operation Plan states: When accepting sludge from a new source or distributor, [Republic] will obtain information regarding the characteristics and constituents of the sludge, including a description of the industrial process or circumstances that resulted in the generation of the sludge. Upon delivery of the sludge, [Republic] will mix lime, sodium hydroxide, or any other suitable agents to eliminate objectionable odors as required during disposal of the sludge before the material is covered. Furthermore, [Republic] will obtain advance notice from contributors prior to delivery of any sludge and shall promptly cover any sludge unloaded on the landfill working face within one (1) hour from the time of unloading, except in the event of exigent circumstances, such as severe weather. [Republic] shall use its best efforts to avoid accepting or disposing of sludge on Saturdays, Sundays, or public holidays. Additionally, with respect to sludge received from wastewater treatment facilities only, such sludge shall not exceed the lesser of (1) twenty percent (20%) of the total volume of waste disposed in the landfill on an average monthly basis, determined annually on the prior calendar year, or (2) two-hundred (200) tons per day, averaged over the prior 12-month calendar year. Republic is required to monitor combustible gases quarterly and transmit the results to DEP, according to the Operation Plan. If Republic detects methane above the limits specified in Florida Administrative Code Rule 62-701.530 (2010), Republic must submit a gas remediation plan to DEP within seven days. The Operating Plan indicates that the separation of the waste from the groundwater prevents the saturation of the waste and, thus, the generation of odor. Sloping and compacting will promote stormwater runoff, again to discourage the generation of odor. The Construction Permit authorizes construction of the proposed landfill in accordance with the "rules[,] . . . reports, plans and other information" submitted by Republic "(unless otherwise specified)." This parenthetical reference provides that the provisions of the Construction Permit control over any contrary provisions in the other documents that are part of the Permit due to incorporation by reference. In addition to the original Application, RRAI, and drawings, the Construction Permit also incorporates Florida Administrative Code Chapter 62-701 (2001). The Construction Permit states that Republic may not violate the prohibitions set forth in Florida Administrative Code Rule 62-701.300, which is discussed in the Conclusions of Law. Construction Permit Specific Condition A.9.a requires notification to DEP of the discovery of limestone during excavation or discovery. Specific Condition A.9.b requires notification to DEP of any surface depressions or other indications of sinkhole activity onsite or within 500 feet of the site. Specific Condition A.9.c prohibits open burning. Construction Permit Specific Condition C.1.b prohibits the discharge of leachate, during construction or operation, to soils, surface water, or groundwater outside the liner and leachate management system. Specific Condition C.4 prohibits the acceptance of hazardous waste and does not condition this prohibition on Republic's knowledge that the waste is a hazardous waste. Specific Condition C.5 requires Republic to "control . . . odors and fugitive particulates (dust)" and "minimize the creation of nuisance conditions on adjoining property." "Nuisance conditions" include "complaints confirmed by [DEP] personnel upon site inspection." Specific Condition C.5 orders Republic to "take immediate corrective action to abate the nuisance" and to "control disease vectors so as to protect the public health and welfare." Construction Permit Specific Condition C.6.b requires immediate notice to DEP of any sinkholes or other subsurface instability. Specific Condition C.8 requires Republic to manage leachate in accordance with the Operating Permit and Florida Administrative Code Rule 62-700.500(8). The Operating Permit incorporates the same materials that are incorporated into the Construction Permit, again "(unless otherwise specified)." Like the Construction Permit, the Operating Permit incorporates Florida Administrative Code Chapter 62-701 (2001) and requires immediate notice to DEP in the event of a sinkhole or subsurface instability. The Operating Permit specifies that the action leakage rate is 100 gallons per acre per day and the leachate recirculation rate is 12,000 gallons per day. As modified by the Joint Stipulation to Permit Modification, Operating Permit Specific Condition A.1.b states: This Facility is not authorized to accept Garbage; untreated Biomedical Waste; animal carcasses; liquids and non-liquid PCB containing materials or wastes with a PCB concentration greater than or equal to 50 parts per million; Liquid Waste; and aluminum dross. Additionally, this facility is not authorized to accept Household Waste, except waste from residential sources generated as Class III waste. Class III waste means yard trash, construction and demolition debris, processed tires, asbestos, carpet, cardboard, paper, glass, plastic, furniture other than appliances, or other materials approved by [DEP] that are not expected to produce leachate which are a threat to public health or the environment as defined in Rule 62-701.200(14), F.A.C. Based on this authorization to allow certain wastes as described above from residential sources, and since the landfill design, including liner and leachate collection systems, meets the requirements of Chapter 62-701, F.A.C., for Class I landfills, the facility will be entitled to [the] household hazardous waste exemption pursuant to 40 C.F.R. 261.4(b)(1). Specific Condition A.9.c prohibits open burning. Operating Permit Specific Condition C.1.b prohibits the discharge of leachate to soils, surface water, or groundwater outside the liner. Specific Condition C.1.c prohibits the discharge of "residual contaminants," such as gasoline, oil, paint, antifreeze, and polychlorinated biphenyls (PCBs), onto the ground or into surface water or groundwater. Operating Permit Specific Condition C.1.k(1) provides that authorized waste types are those listed in Section 3(b) of the Operations Plan, and unacceptable wastes shall be removed from the site as described in Sections 3(a) and 7. As modified by the Joint Stipulation to Permit Modification, Operating Permit Specific Condition C.1.k(1) provides: "Waste types authorized for management at this site are those listed in Section 3(b) of the Operations [sic] Plan. Unacceptable wastes are those listed in Section 5 [of the Operation Plan] " Operating Permit Specific Condition C.1.k(2) requires the use of a sufficient number of spotters to remove unacceptable wastes, but allows Republic to direct its equipment operators to serve as spotters from the equipment. This condition allows DEP to require that spotters work from the ground, if DEP determines that spotting from equipment is not effective. Specific Condition C.1.k(3) requires Republic to remove unacceptable wastes immediately and not to unload additional wastes in the immediate vicinity until placing unacceptable wastes in the designated waste containers" "near the working face" and within the lined landfill area. Operating Permit Specific Condition C.1.l(2) requires Republic to inspect on each operating day the property boundary for objectionable odors and, if any are detected, abate them in accordance with Specific Condition C.5. Specific Condition C.5.a requires Republic to control odors, disease vectors (insects and rodents), and fugitive particles (dust and smoke) to protect the public health and welfare. Control is defined as "minimiz[ing]" the creation of nuisance conditions on adjoining property. Odors confirmed by DEP personnel are a nuisance condition, and Republic must take immediate corrective action to "abate" the nuisance. Specific Condition C.5.b provides that, if odor control measures do not "sufficiently abate" objectionable odors within 30 days, Republic will submit an odor remediation plan to DEP for approval. Operating Permit Specific Condition C.8.e requires monthly reports to DEP of leachate quantities. Specific Condition C.8.h(1) prohibits recirculation of leachate at rates that result in seepage that may discharge outside the lined area. Leachate may not be sprayed when the application area is saturated or during a rainfall event. There is no prohibition against spraying during windy conditions. Operating Permit Specific Condition E details the extensive water quality monitoring requirements. However, Specific Condition E.9.b requires only annual testing of the five field parameters, eight laboratory parameters, and the comprehensive list of Appendix II parameters set forth in 40 CFR Part 258, all of which are identified below. Specific Condition E.9.c provides that, if a contaminant listed in 40 CFR 261.24 exceeds the level listed therein, Republic will notify DEP and take monthly leachate samples until no exceedances are detected for three consecutive months. Operating Permit Specific Condition F.1.a states: "This solid waste permit will meet the statutory requirement to obtain an air construction permit before . . . constructing a source of air pollution, except for those landfills that are subject to the prevention of significant deterioration (PSD) requirements of Chapter 62-212, F.A.C." Such facilities are required to obtain an air construction permit from the Bureau of Air Regulations prior to construction. Specific Condition F.1.b requires Republic to comply with Title V of 40 CFR 60, Subparts WWW and CC. This section notes that Title V permit applications must be submitted to the District Air Program Administrator or County Air Program Administrator responsible for the landfill. Aviation Safety Landfills attract birds in search of food. Flying birds may interfere with aviation safety. Thus, landfills are typically not located in close proximity to airfields to minimize the risk that flying birds will interfere with airborne aircraft approaching or departing from an airport. The nearest airport to the Cedar Trail Landfill is the Bartow Municipal Airport, which is operated by the Bartow Aviation Development Authority. This airport is over five miles from the footprint of the active landfill and 4.6 miles from the boundary of the proposed site. Republic provided notice of the Application to all airports within six miles of the proposed landfill, the Federal Aviation Administration, and the Florida Department of Transportation. None of these entities objected to the proposed landfill. When Republic gave the Bartow Aviation Development Authority notice of an earlier application, which sought a permit for a landfill that would accept garbage, the authority objected to the proposal due to concerns posed by birds to aviation safety. When asked about the Application, the authority's executive director testified that she still has concerns about the proposed landfill, but she did not specify the nature of her concerns or her analysis. As explained in the Conclusions of Law, these are the only facts required for a determination of whether Republic has provided reasonable assurance of aviation safety. The record provides no basis for finding that Republic has failed to provide reasonable assurance of aviation safety. Neither the FAA nor the Bartow Aviation Development Authority has objected to the proposed landfill. The executive director's unspecified concerns do not override the absence of a formal objection from these agencies. Petitioners assign too much weight to the earlier objection submitted by the authority. The composition of the authority may have changed or some authority members may have decided they were wrong in their earlier analysis. This earlier objection does not outweigh the absence of objection to the present proposal from any of the aviation agencies and the absence of any evidence of the expected nature or extent of bird usage of the proposed landfill and the extent to which these birds would interfere with existing and expected flight paths of aircraft using the Bartow Municipal Airport. Public Health Petitioners' expert witness on public-health issues, Dr. David Carpenter, is a medical doctor with a long, prestigious history of public service, including with the Department of Defense, the National Institutes of Mental Health, the United States Public Health Service, and the New York Department of Health, where he served as director from 1980-85. At that time, Dr. Carpenter started the School of Public Health at the University of Albany. Republic's expert witness on public-health issues, Dr. Christopher Teaf, is an expert in the evaluation of environmental contamination, waste management, and toxicology, but not a medical doctor. Dr. Teaf is a professor at Florida State University and owns a small consulting firm. The major part of Dr. Carpenter's career has been devoted to research. For the past ten years, he has focused more on human health, especially human disease from exposure to environmental contaminants. Dr. Carpenter has considerable experience with the adverse effects of landfills on human health, but his experience has been mostly with older landfills, where containment measures were few and offsite releases were many. Clearly, Dr. Carpenter's experience does not extend to the role of landfill design, construction, and operation in the transmission of human disease. Thus, Dr. Carpenter is qualified to opine on the effects of pollutants that may escape landfills, but not on the relationship of landfill design, construction, and operation on the probability that a landfill will transmit pollutants. For the most part, Dr. Carpenter did not attempt to address matters outside of his expertise. However, Dr. Carpenter testified that the risk of disease or injury increased in relationship to the proximity of the person to the landfill. This testimony can only be credited if one assumes that the landfills are identical in terms of design, construction, and operation and in terms of the environmental conditions of the landfill site. In other words, in real-world applications, it is impossible to credit this element of Dr. Carpenter's testimony, especially to the extent of his implicit suggestion that public health is unreasonably endangered by the construction of a landfill, in compliance with all rules, that satisfies all of the separation criteria and design criteria set forth in the rules, as discussed below. By contrast, Dr. Teaf focused on the details of the proposed landfill. Applying his knowledge of toxicology, Dr. Teaf determined that the proposed landfill adequately protects public health. In making this determination, Dr. Teaf analyzed the effects of various design and operational characteristics of the proposed landfill, including the double liner system, the leachate collection and management system, the selection of appropriate waste types, the procedures for the evaluation and covering of sludges, the prohibition against municipal garbage, the restrictions on household items, the monitoring of groundwater and surface water, the stormwater management system, and the plans to control dust and odors. Dr. Carpenter's testimony and the literature that he sponsored suggested important links between older landfills and a wide range of human disease. But the recurring problem with Dr. Carpenter's testimony and the research articles that he sponsored was the inability to link this information to the proposed landfill. All of the landfills studied in his research articles were older, and most of them appeared to have been designed, constructed, and operated under far more relaxed regulatory regimes than exist today. Nothing in Dr. Carpenter's testimony or sponsored literature attempted to delineate the design or operational characteristics of these landfills, such as whether they were double- or even single-lined, served by leachate circulation and recovery systems, limited as to materials that they could accept, or required to install stormwater management and water monitoring systems. 93. Analysis of the risk to public health posed by the proposed landfill requires consideration of the various means of transmission of the pollutants received by the landfill: water, land, and air. Of these, water requires little analysis, on this record. Even Dr. Carpenter conceded that the proposed landfill does not appear to pose a threat to groundwater. The double liner, leachate collection and recovery system, and groundwater monitoring plan support the finding that groundwater transmission of pollutants from the proposed landfill is unlikely. Transmission by surface water is also unlikely. Compared to groundwater monitoring, surface water monitoring is limited. For instance, there is only a single monitoring site. Also, as noted above, the stormwater pond for the leachate storage area is expected to discharge stormwater offsite during excessive storm events, at which time surface water samples will be taken. However, a comprehensive surface water management system is in place at the landfill and will prevent offsite discharges in all but a few excessive rain events. Transmission by land is also unlikely. The Application contains engineering analysis of the proposed stability of the side slopes and a determination that they will be stable. The discussion of sinkholes, below, does not affect this finding. Treating dust as transmission by air, the only other means by which pollutants may transmit by land is by animals, such as insects, rodents, and birds. An important factor limiting the activity of animals in spreading pollutants offsite is the fact that the proposed landfill will not receive garbage. Although putrescible waste may be received within other categories of waste, the prohibition against receiving garbage will greatly reduce the amount of potential food sources for animals and thus the utilization rate of the proposed landfill by these animals. A further reduction in animal utilization will be achieved through the daily and intermediate cover requirements. Thus, transmission of pollutants by animals is also unlikely. Transmission by air takes several forms. Pollutants may be transmitted as or on dust, with water in the form of aerosol, or as gas. In terms of how transmission by air is addressed by the Permit, this means of transmission potentially represents a greater threat than transmission by water or land for four reasons. First, the explicit focus of the Permit, as to gas, is to avoid explosive concentrations of methane and objectionable odors, but not the transmission of other pollutants by air. Second, the effect of the Permit is to prohibit the release of pollutants into the groundwater or offsite surface water and to prohibit the release of pollutant-bearing land offsite, but no such flat prohibition applies to the offsite release of pollutants by air. Third, the leachate recirculation system provides a good opportunity for the release of certain pollutants into the air by aerosol or evaporation, but similar releases to offsite land, surface water, or groundwater are prohibited. Fourth, scientific understanding of the effects of exposure, especially by inhalation, to pollutants, especially in the form of organic compounds, is continuing to develop: with the use of chemicals increasing three fold in the 50 years preceding 1995 and approximately 80,000 chemicals in use in 2002, only a few hundreds of these chemicals have been subjected to long- or short-term study, resulting in the discovery that about 10% of the chemicals in use in 2002 were carcinogens. Transmission by dust appears to be limited by the frequent covering and spraying of the working faces. Although nearby residents complain of dust in their homes, the practices of the less-regulated Class III landfill cannot be extrapolated to the proposed Class I landfill. Thus, the prospect of dust transmission of chemicals contained in the fill received by the proposed landfill appears also to be slight. The use of untreated leachate as the spray medium to control the dust itself raises two risks, however. First, spraying leachate will release chemicals in aerosol. The potential range of aerosol is great, especially as the landfill ascends toward its design height of 190 feet. However, the risk of transmission by aerosol is reduced to insubstantial levels by adding a Permit condition that prohibits spraying during windy conditions. Second, depositing leachate on the landfill face will release chemicals through evaporation. The point of spraying the landfill face is to control dust between the addition of the waste materials to the pile and the application of the cover. Between these two events, dry conditions will sometimes intervene and may cause the evaporation of certain, but not all, pollutants. The leachate acquires pollutants as it percolates down the waste column and into the leachate collection system. As Dr. Teaf noted, the leachate becomes more concentrated as it recirculates, but, otherwise, this record is largely silent as to the likely composition of the recirculated leachate. However, for landfills accepting sludge, higher levels of mercury may be present in the leachate. As reported by the Florida Center for Solid and Hazardous Waste Management at the University of Florida, in a report issued March 2007, and titled, "Design and Operational Issues Related to Co-Disposal of Sludges and Biosolids and Class I Landfills--Phase III," one study found that the concentration of mercury in the leachate of landfills that receive sludge is almost three times greater than the concentration of mercury in the leachate of landfills that do not accept sludge. The same study reported that total dissolved solids and chlorides were present at greater concentrations at the landfills that did not accept sludge and that other parameters--unidentified in the cited article--were not significantly different between the two types of landfills. Republic proposes to recirculate substantial volumes of leachate--sufficient, for instance, to raise the moisture content of the fill from 25 percent to 28.9 percent. The Permit allows the proposed landfill to operate six days per week, for a total of 312 days annually. The Operation Plan prohibits the application of leachate during rain, but the number of days annually during which rain extends for the entire day is few, probably no more than a dozen. These numbers suggest that Republic may apply as much as 3.6 million gallons annually of untreated leachate to the landfill face. The 12,000 gallon-per-day limit and restrictions on head in the leachate collection and removal system effectively limit the quantities of leachate that may be recirculated, but the sole provision addressing leachate water quality is the annual monitoring event described above. Given the time required to analyze the many parameters included in the EPA regulation, for most of the year between tests, Republic will be applying over three million gallons of leachate whose pollutant concentrations will be completely unknown. Some assurances emerge, though, when considering air transmission of pollutants by class. In general, on this record, as to transmission by gas, there appears to be an inverse relationship between a compound's volatility, which is a measure of its ability to enter the air, and a compound's persistence. VOCs are one of the most dangerous classes of pollutants to public health and include such carcinogens as benzene, tolulene, xylene and, the most dangerous of all VOCs, vinyl chloride, which is released upon the degradation of such common substances as plastics, carpets, and upholstery. Biogas, which is generated by the anerobic decomposition of organic compounds in a landfill, contains mostly methane and carbon dioxide, but also significant levels of VOCs. When inhaled, the primary results of exposure to VOC are respiratory irritation and allergenic effects. Volatility is measured by vapor pressure, which is a measure of a chemical's ability to get into the air. As their name suggests, VOCs enter the air easily. They are also capable of traveling great distances due to their light molecule. However, VOCs are easily destroyed by sunlight and diluted by wind. Other organic compounds common to landfills are only semi-VOCs, such as PCBs. Although less volatile, these chemicals, too, are hazardous to public health--in the case of PCBs, in any amount. Due to this fact and their persistence in the environment, the United States has prohibited the manufacture of PCBs for over 30 years. However, not only are PCBs considerably less likely to enter the air than VOCs, they also travel shorter distances than VOCs due to a heavier molecule. Dr. Carpenter opined that there is little evidence that PCBs are an issue in the proposed landfill. Another class of organic compound, 1000 times less volatile than even PCBs, is phthalates, which are used in the production of plastics. Phthalates pose significant threats to public health, especially reproductive health. However, the exceptionally low volatility of this compound renders transmission by evaporation highly unlikely. Much of the regulatory framework imposed on landfill design, construction, and operation arises out of concerns for the control of human pathogens, which are infection-causing organisms, such as bacteria, viruses, protozoa, and parasitic worms. One of the great advances in human longevity in the United States occurred in the early 1900s--not with the development of antibiotics or improved medical care--but with the implementation of basic sanitation control and the removal of pathogens from the drinking water. For the proposed landfill, sludge will be the primary source of pathogens. Sludge is nutrient-rich organic matter, which will be received at the proposed landfill without any treatment except possibly dewatering. Even with the acceptance of sludge, the proposed landfill presents little risk for the transmission of pathogens. Pathogens communicate disease only when a person is exposed to an effective dose and are better transmitted by direct contact or animal than air. Bacterial pathogens are themselves killed by wind, as well as sunlight, temperature, and humidity differentials, so the preferred means of air transmission would be aerosol versus gas. The record permits no findings as to the persistence of pathogenic viruses, protozoa, and parasitic worms. However, as noted above in connection with the land transmission of pathogens, the immediate application of lime and cover to the sludge will tend to prevent the release of effective doses of pathogens by air, as well. The last major class of pollutant that could be transmitted by air is heavy metals, such as mercury or lead. Although these metals produce a wide range of neurological diseases and generally interfere with cognition and behavior, Dr. Carpenter admitted that heavy metals were not as much of a concern as VOCs, presumably due to their resistance to vaporization. Even though transmission by air is not as tightly controlled as transmission by water or land, for the four reasons noted above, there is little risk of transmission by air--i.e., dust, aerosol, or gas--when the specific properties of likely pollutants are considered. In all but five respects, then, Republic has provided reasonable assurance that public health will not be endangered by pollutants released from the landfill by water, land, or air. First, to provide reasonable assurance concerning public health, the Permit needs a condition that prohibits spraying leachate during windy conditions, which DEP may define as it reasonably sees fit. As noted in the Conclusions of Law, this is a requirement in the rules and, due to its importance, should be restated explicitly in the Permit, which restates numerous other rule requirements. Second, to provide reasonable assurance concerning public health, the Permit needs more frequent monitoring of leachate water quality, at least at the frequency, as noted in the Conclusions of Law, set forth in the rules. Large volumes of untreated leachate will be recirculated through the landfill. Even if aerosol transmission is controlled, transmission by evaporation of some pollutants, although not the heavy metals, is possible. Also, pollutants are concentrated in recirculated leachate and thus the consequences of transmission into groundwater or surface water, however unlikely, become greater. At the same time, the action leakage rate is generous--to Republic, not the groundwater. At 100 gallons per acre per day, Republic is not required to report to DEP possible liner leakage until about 7300 gallons per day are lost to the surficial aquifer. Suitable for the detection of catastrophic failures associated with most sinkholes, this action leakage rate is too high to trigger action for small liner leaks. If Republic is to be allowed this much leakage into the groundwater, it must identify the leachate's constituents and their concentrations at least semi-annually. Third, to provide reasonable assurance concerning public health, the Application must extend the right of split testing to all of the parties in these cases, if DEP fails to exercise its right to take a split sample. The spraying of untreated leachate and generous limit applied to liner leakage before reporting and remedial action are required underscore the importance to public health of independent leachate testing. There is no reason to allow budgetary constraints or administrative oversight to preclude Petitioners and Intervenor, who are uniquely situated to suffer from the escape of excessive pollutants in the leachate, from providing, at their expense, this independent leachate testing. Fourth, to provide reasonable assurance concerning public health, the Permit needs to restate accurately the language of the rules concerning the extent of knowledge required of Republic, if it is to be liable for the acceptance of certain prohibited wastes. Fifth, to provide reasonable assurance concerning public health, the Permit needs to be modified to ensure that at least one spotter, whose sole responsibility is spotting, will be assigned to each working face while the landfill is receiving waste. Sinkholes The sinkhole issue arises in the geotechnical analysis of the sufficiency of the foundation to support the considerable loads of a landfill and also in the stability of the side slopes of the landfill. This analysis starts with consideration of the geology of the area, of which Republic's property is a part, and, among other things, the potential for sinkhole formation in the area. The Cedar Trail Landfill lies within the Bartow Embayment and along the eastern slope of the Lakeland Ridge of the Central Lake District Physiographic Province. This embayment is a large erosional basin partially backfilled with phosphatic sand and clayey sand of the Bone Valley Member. At this location, the top of the Floridan Aquifer is formed by Suwannee Limestone, which consists of white to tan, soft to hard, granular, porous, very fossiliferous limestone with interbedded dolomite. This rock unit is 110-140 feet thick. Atop the Suwannee Limestone sits the Hawthorne Group, which comprises the Arcadia Formation, at the base of which is the Nocatee Member, which is a relatively impermeable sand and clay unit. Atop the Nocatee Member is the Tampa Member, which consists of hard, dense, sandy, locally phosphatic, fossiliferous limestone. The top of this member, which is the top of the Arcadia Formation, is locally referred to as the "bedrock complex," which marks the lower limit of phosphate mining. Atop the Arcadia Formation, still within the Hawthorne Group, sits the Peace River Formation, which consists of phosphatic clayey sand and clayey sand. The lower portion of the Peace River Formation is a relatively impermeable, undifferentiated clayey unit locally known as "bedclay." The Bone Valley Member of the Peace River Formation is mined for phosphate and is locally known as "matrix." Atop of the Peace River Formation are undifferentiated surficial soils, typically consisting of silty sand, clayey sand, and some hardpan and organic soils. These materials are locally known as "overburden." Phosphate mining is prevalent in the area, including, as noted above, much or all of the Cedar Trail Landfill site. Strip mining for phosphate normally removes the entire surficial aquifer, just into the bedclay. Mined areas are then backfilled with overburden spoil soils, clay, waste clay, and sand tailings. After backfilling, the soil strata bear little resemblance to premining strata. Sinkholes are prevalent in the general area surrounding the Cedar Trail Landfill. A sinkhole is a surface depression varying in depth from a few feet up to several hundreds of feet and in area from several square feet to several acres. Sinkholes are typically funnel-shaped and open broadly upward. Sinkholes form when weakly acidic groundwater creates cavities in the calcium carbonate within limestone. Soils above these cavities erode into the cavities. In the area that includes the Cedar Trail Landfill, cover-collapse and cover- subsidence sinkholes predominate among sinkhole types. A cover-collapse sinkhole, which is typically steep- sided and rocky, forms when cohesive soils over a limestone cavity can no longer bridge the cavity under the weight of overlying soil and rock. At this point, the cohesive soils suddenly collapse into the cavity. These are more common in the part of the state in which the Cedar Trail Landfill is located. A cover-subsidence sinkhole occurs due to the gradual lowering of the rock surface as solutioning occurs in the subsurface rocks. This type of sinkhole develops as subsurface soluble rock is dissolved and overlying soils subside into the resulting shallow surface depressions. Regardless of the type of sinkhole, borings into sinkholes will reveal zones of very loose soil sediments that have washed downward into the cavernous voids within the bedrock. This very loose soil zone is called a raveling zone, which starts at the limestone layer, as the overlying soils begin to collapse into the solution features within the limestone. As the loosening works its way upward toward the surface, it eventually results in the subsidence of the ground surface and formation of a sinkhole. Considerable sinkhole activity has taken place in the immediate vicinity of Republic's property. Most visibly, a sinkhole formed in 2006 in 285-acre Scott Lake, 4.5 miles northwest of the landfill. This sinkhole drained the entire lake and destroyed several structures. The Florida Geological Service sinkhole database, which consists of anecdotal reports of sinkhole activity, some of which are unverified, includes 49 sinkholes within five miles of the proposed landfill. Two documented sinkholes have occurred within .17 mile of the landfill--one of which is reported to be 125 feet in diameter and 80 feet deep. Based upon the information contained in the preceding paragraph, Clint Kromhout, a professional geologist with the Florida Geological Survey, opined on August 23, 2009, that the potential for sinkhole formation "within the proposed site and surrounding area" is "low to moderate." Mr. Kromhout does not provide a definition of "low," but part of his opinion is shared by the Golder Report, which agrees that the sinkhole potential on the proposed site is "low." The potential for sinkhole formation in the general area surrounding the proposed landfill, as distinguished from the site itself, is at least moderate. In their Proposed Recommended Order, Republic and Intervenor necessarily concede: "All parties acknowledge that the proposed landfill site is in a general region that has a relatively high frequency of sinkholes as compared with the rest of the state of Florida." It is misleading to characterize the area surrounding the proposed landfill as of low potential for the formation of sinkholes, unless there is another category, like "nonexistent." But characterizing the sinkhole potential of the surrounding area as moderate is not determinative of the likelihood of sinkholes at the landfill's footprint, nor is a site-specific geotechnical investigation mooted by such a characterization. Rather, characterizing the sinkhole potential of the surrounding area as moderate dictates the intensity and scope of the ensuing geotechnical investigation, if the investigation is to provide reasonable assurance of the structural integrity of the proposed landfill. Acknowledging moderate potential for sinkhole formation in the surrounding area, Republic has appropriately relied on three geotechnical reports, including three sets of boring data. The final of these reports, the Hanecki Report, is based on the collection and analysis of boring data, as well as a review of the data and analysis contained in the two earlier geotechnical reports, the Ardaman Report and Golder Report. The boring data reveal that the proposed landfill site features four units. Nearest the surface is Unit 1, which is brown to dark brown, medium- to fine-grained sand with minor amounts of clayey silt. Unit 1 is 0-10 feet thick. Next down is Unit 2, which is tan to gray, medium- to fine-grained sand with increasing silty clay or clayey silt. Unit 2 is 5-10 feet thick and generally marks the upper limit of fine-grained, granular soils (i.e., clayed sands and silty sands). Unit 3 is orange brown to yellow brown, gray and tan silty clay to clayey silt or fine sand and silty clay. Unit 3 is 5-15 feet thick. Unit 4 is gray and tan clayey silt or silty clay with minor amounts of fine sand. This material is very stiff or very dense, and most borings terminated in this unit. The few borings that penetrated this unit suggest that it may consist of dolomitic sandy clays and silts and dolomitic limestone to depths greater than 100 feet below grade. Units 3 and 4 generally mark the upper limits of low permeability/low compressibility soils. The Hanecki investigation comprised two main steps. First, Hanecki retained a subconsultant to perform electrical resistivity imaging (ERI) along 100-foot-wide transects run across the site. Any anomalies revealed by the ERIs were to be followed by standard penetration test (SPT) borings, which permit soil testing at predetermined intervals, as well as a measure of the compressibility of the soils. Compressibility is measured during the soil-testing intervals, during which the drill bit is replaced by a soil sampler. The driller records the number of blows required for a 140-pound hammer falling 30 inches to produce 12 inches of penetration. The value is expressed in N-values, where N represents the number of such blows. Looser soils produce lower N values. Another important piece of information obtained during SPT boring is the partial or total loss of circulation fluid during drilling. While the drill is penetrating soil, a slurry circulates through the borehole to prevent the collapse of the sides of the hole. This slurry is recycled during drilling, but, if the drill encounters a void, all or part of the circulation fluid is lost. The ERI survey revealed no real anomalies because of a narrow range of resistance values. However, taking relatively small differences in resistivity as an anomalies, Hanecki identified 14 features of interest. At each of these locations, Hanecki performed an SPT boring. Because the ERI transects were unable to span the two onsite ponds, Hanecki added two locations for SPT borings adjacent to each side of each pond, for a total of four additional SPT borings. At the request of DEP, Hanecki added a nineteenth SPT boring at Golder site G-11, which had revealed low N-values during Golder's borings. Hanecki extended the borings into "refusal" quality soil, which was defined as soils requiring more than 50 blows of the 140-pound hammer to achieve six inches or less of penetration. All of Hanecki's SPT borings encountered very hard limestone. Among the most significant findings of Hanecki's borings, only one boring, G-11, experienced any circulation fluid loss, and this was estimated at 50 percent. However, it is more likely that this partial circulation fluid loss is due to loosely deposited sands than a void that might be indicative of conditions suitable for sinkhole formation. Not all circulation losses indicate voids that that will result in sinkhole formation. Also significant among Hanecki's findings is a clayey soil, or bedclay, at every SPT boring, which severely limits hydraulic recharge to the limestone. By impeding vertical migration of surface and shallow subsurface water to the limestone layer, this bedclay "greatly inhibits limestone erosion." This bedclay also supports the looser soils above the bedclay and thus prevents raveling, without which sinkholes cannot form. Two borings--G-11 and F3-1--lacked a layer of Unit 3 or 4 soil above the limestone, but Hanecki concluded that the Unit 2 layers above the limestone at these locations contained sufficient clay or clayey sand to serve the same functions of impeding the downward movement of groundwater and preventing the downward movement of loose soils. This conclusion appears reasonable because Unit 2 is the uppermost reach of the finer- grained materials, of which clays and silts are examples when compared to sands. There is obviously some variability in the distribution of finer- and coarser-grained materials within each occurrence of Unit 2 soils. Hanecki's findings indicated intervals of loose soils, sometimes at depth, which typically would suggest raveling zones. At the proposed location, though, these findings do not support raveling due to the underlying bedclay layer and the history of mining, which probably introduced looser soils typically found closer to the surface through the entire 40-foot depth of the mine cut. Based on these findings, the Hanecki Report concludes that, regardless of at least moderate potential for sinkhole potential in the area, the footprint of the proposed landfill has an acceptably low risk of sinkhole development to permit development of the proposed landfill. This is a reasonable conclusion because it is supported by the data collected by Hanecki and his reasoned analysis of these data. Hanecki's conclusion is also supported by the data and analysis contained in the Golder Report and Ardaman Report, which are based on an additional 84 SPT borings, post- reclamation. Only about 12 percent of these SPT borings reached the limestone, and they cover all of Republic's property, not merely the footprint of the proposed landfill. Even so, these borings confirm two important findings of the Hanecki Report. First, they produced data indicative of an extensive bedclay layer intact on Republic's property. Second, the Ardaman and Golder borings reveal only two or three instances of partial circulation loss that, like the sole occurrence of partial circulation loss in the Hanecki borings, are located on Republic's property, but outside the footprint of the proposed landfill. Republic has provided reasonable assurance that the site will provide an adequate foundation for the proposed landfill and sinkholes are unlikely to undermine the structural integrity of the proposed landfill.
Recommendation It is RECOMMENDED that the Department of Environmental Protection enter a final order granting the Construction Permit and Operation Permit, but only if the Operation Permit is modified by the addition of the five items identified in paragraphs 172, 174, 175, 181, and 187. DONE AND ENTERED this 8th day of October, 2010, in Tallahassee, Leon County, Florida. S ROBERT E. MEALE Administrative Law Judge Division of Administrative Hearings The DeSoto Building 1230 Apalachee Parkway Tallahassee, Florida 32399-3060 (850) 488-9675 SUNCOM 278-9675 Fax Filing (850) 921-6847 www.doah.state.fl.us Filed with the Clerk of the Division of Administrative Hearings this 8th day of October, 2010. COPIES FURNISHED: Lea Crandall, Agency Clerk Department of Environmental Protection Douglas Building, Mail Station 35 3900 Commonwealth Boulevard Tallahassee, Florida 32399-3000 Tom Beason, General Counsel Department of Environmental Protection Douglas Building, Mail Station 35 3900 Commonwealth Boulevard Tallahassee, Florida 32399-3000 Mimi A. Drew, Secretary Department of Environmental Protection Douglas Building, Mail Station 35 3900 Commonwealth Boulevard Tallahassee, Florida 32399-3000 Ronald L. Clark, Esquire Clark, Campbell & Mawhinney, P.A. 500 South Florida Avenue, Suite 800 Lakeland, Florida 33801-5271 William D. Preston, Esquire William D. Preston, P.A. 4832-A Kerry Forest Parkway Tallahassee, Florida 32309-2272 Jennings Kemp Brinson, Esquire Clark, Campbell & Mawhinney, P.A. 500 South Florida Avenue, Suite 800 Lakeland, Florida 33801 Sean R. Parker, Esquire Boswell & Dunlap, LLP 245 North Central Avenue Bartow, Florida 33830-4620 Ralph A. DeMeo, Esquire Hopping, Green, & Sams, P.A. 119 South Monroe Street, Suite 300 Tallahassee, Florida 32301 Stanley M. Warden, Esquire Department of Environmental Protection 3900 Commonwealth Boulevard, Mail Station 35 Tallahassee, Florida 32399-3000 Paula L. Cobb, Esquire Hopping Green & Sams, P.A. Post Office Box 6526 Tallahassee, Florida 32314 John W. Frost, Esquire Frost Sessums Van den Boom & Smith, P.A. Post Office Box 2188 Bartow, Florida 33831 John Stanley Fus Highland Lakes Estates HOA 2190 Boardman Road Bartow, Florida 33830
Findings Of Fact The proposed site consists of some 311 acres bounded on the South by Alligator Alley (SR 84) and is approximately 6 1/2 miles East of SR 858. The existing solid waste disposal facility at the airport is exceeding the capacity of the area to absorb any additional solid waste. An approved federal grant for expansion and improvement of the Naples airport is contingent upon the cessation of further solid waste disposal at this site. The original deadline for discontinuing use of the airport disposal site of June 30, 1975 has been extended to allow the processing of the instant application. Of the numerous sites considered the one proposed herein was considered by local, state, and federal agencies to be the best overall. The proposed site meets the requirements of, and has been approved by the USDA Soil Conservation Service, the Department of Environmental Regulations, and various state health organization. The plans and specifications which have been submitted by the county and approved by the various agencies concerned called for an excavation of the site to a depth of approximately 3 feet, with the solid waste after compaction being placed in the ground and each layer thereafter placed on top and covered on a daily basis with soil. A perimeter canal will be constructed around the site to divert surface water from outside the site to prevent flooding the area. Interior canals will be installed to provide for collection of the leachate, as well as water falling on the site. The project includes construction of leachate sump ponds on the site, which will be coated to preclude the leachate from percolating into the surrounding area. An all weather access road will be provided to the site, and the only vehicles permitted on the site will be those controlled by the county and city, which would include their contractor for hauling waste. The routes for these vehicles would be such that they would not pass' over the Golden Gate Boulevard, which goes through the community of Golden Gate. At the hearing little new evidence was submitted. Intervenor appeared to take the position that its opposition to the project was based upon the fact that: (1) The site proposed could flood; (2) An impermeable barrier should be installed in all cells to preclude harmful materials from permeating the soil; and (3) Leachate from the cells could enter into the ground water table. Testimony with respect to these objections revealed: (1) The pumping system proposed is adequate to handle any flooding that may reasonably be anticipated; (2) The site is not located on a watershed that could go to a public water supply; (3) The site is some 5 or 6 miles from the nearest public water supply and not so located that surface water from the site could flow to a public water supply; (4) No place in Collier County meets the 5 foot separation provision between water table and place where waste could be dumped; The safeguards provided by the proposed plan qualifies this site for waiver of provision (4) above; (5) If an impermeable barrier was installed beneath the cells it would be ineffective in preventing surface water contamination in the event the site is flooded; (6) In the event the proposed system proves inadequate to control flooding, modifications in the then existing system could be made that would control this problem; and (7) Use of impermeable barrier below cells is but one design method to meet requirements of the various regulatory agencies.
Findings Of Fact As a part of its solid waste disposal program, the City of Naples operates a yard trash compost site adjacent to the Gordon River within the city limits. A fifteen (15) acre site has been leased from a private owner, and the lease requires that the City operate the site in compliance with permitting requirements. The site is intended to received only horticultural yard trash. The City picks up such trash in trucks, and delivers it to the site. Cells, or ditches, have been excavated at the site to a depth of approximately six (6) feet. The trash is deposited into the cells. The cells are excavated to a depth below the ground water level, so the trash is placed directly into the ground water. Although only horticultural yard trash is intended to be disposed of at the site, and although the City attempts to enforce this intention, household garbage including food waste frequently finds its way into the cells. The City has been utilizing this site in this manner for approximately fifteen (15) years, and for at least the past ten (10) years has operated under all required local and state permits. The City is presently operating the site in accordance with a permit issued by the Department of Environmental Regulation on December 31, 1976. The permit expires on January 1, 1980. Sometime in February, 1979, the Department first gave notice to the City that the yard trash compost site was not being operated in conformity with all applicable rules and regulations. Specifically the Department advised the City that the site violated the provisions of Rule 17-7.04(2)(a), Florida Administrative Code, because solid waste was deposited within 200 feet of a natural water body (the Gordon River) and Rule 17-7.04(2)(f), because solid waste was deposited in an area where the water table was less than five (5) feet below the normal ground surface. Rule 17-7.04(2)(f) was modified during the course of this variance application proceeding. The rule now requires that solid waste not be deposited directly into the ground water. The City's site neither conformed with the rule in effect in February, 1979, nor with the present modified rule. The Department and the City agreed that the City could continue to operate the site pending the completion of this proceeding, and, until all present cell excavations are filled. Yard trash compost sites such as that operated by the City do not involve as profound a threat to water quality as do more generalized solid waste disposal sites. Nonetheless placing of large quantities of yard trash at or in water bodies will cause infusion of large quantities of nutrients into the water body. The composting or breaking down of yard trash can take place under either aerobic or anaerobic conditions. Aerobic decomposition takes place where vegetation is exposed to oxygen. Anaerobic decomposition takes place where there is no oxygen. If vegetation is covered by water or soil it will not have oxygen. The materials will only partially decompose through a process called fermentation. Such material, when not fully decomposed, cannot be fully compacted nor reduced in volume as would happen with aerobic decomposition. The system utilized by the City of Naples therefore will result in a springy texture to the area. When decomposition takes place above ground, and vegetation is exposed to oxygen, the Vegetation can break down into its primary elements, resulting in a humus material which can be utilized to condition soil, and which will become part of the soil and stabilize the soil. The City's method of disposal introduces very concentrated amounts of organic substances into the ground water. There is thus a large increase in nitrogen and phosphates in the ground water. Placing such large quantities of organic material into the ground water effectively pollutes the ground water. There is a shallow water aquifer below the surface level at the trash compost site. Below this aquifer is a layer of sand, marl and rock which is not highly permeable. Below this layer lies a second aquifer which is an important source of drinking water in the area. Trash at the compost site under the City's present system is deposited directly into the upper aquifer. This water flows either into the Gordon River adjacent to the site, or more slowly permeates down into the lower aquifer. Placing the organic materials into the ground water thus constitutes a serious source of pollution either to the Gordon River, or to the lower aquifer, or to both. Certainly it serves to profoundly degrade the water quality of the ground water. The City has operated two (2) test wells adjacent to the site for the past eighteen (18) months. Results of samples taken from these test sites are inconclusive, and do not reveal that the City's disposal system has caused any pollution whatsoever. This does not mean, however, that no adverse impact could have been detected, or that none has taken place. The City's test wells were not placed so that they would intercept the flow of ground water from the site. Even if they had been so placed, testing has taken place only every six (6) months, and not in a manner so that any viable conclusions can be reached. The Department has recently installed test wells, and although data from them is not complete, it does reveal a definite flow of pollutants from the site to the test wells. Although the flow of ground water will serve to dilute the pollutants to some degree, it is inevitable that the ground water supply itself will be degraded, and that eventually either the waters of the Gordon River or of the lower aquifer will also be adversely affected. Under its present system the City estimates that it will be able to utilize the compost site for eight more years. The City has contended that operating the site as an above ground compost site would effectively cut in half the time period over which the site could be utilized and would increase the cost of maintaining the site by requiring additional equipment, and eventually requiring additional equipment for the transporting of yard trash to a remote site. These contentions are not supported by the evidence. In the first place the City could save money in operating the site as an above ground composting site because it would not be necessary to make excavations. Furthermore, above ground composting of the materials would result in usable compost which could be sold as land fill. This could constitute a source of revenue, and also open the site for additional usage.
Recommendation Based upon the foregoing Findings of Fact and Conclusions of Law, it is, RECOMMENDED: That a final order be entered granting the variance application filed by the City of Naples with respect to its request to be relieved from the requirements of Rule 17-7.04(2)(a), with conditions imposed as set out in the Department's notice dated June 21, 1979 (DER Exhibit 4). That a final order be entered denying the exemption request filed by the City of Naples with respect to the requirements of Rule 17-7.04(2)(f). RECOMMENDED this 28th day of November, 1979, in Tallahassee, Florida. STEVEN PFEIFFER Assistant Director Division of Administrative Hearings Room 101, Collins Building Tallahassee, Florida 32301 (904) 488-9675 COPIES FURNISHED: David W. Rynders City Attorney City of Naples 735 8th Street South Naples, Florida 33940 Ray Allen Assistant General Counsel Department of Environmental Regulation Twin Towers Office Building 2600 Blair Stone Road Tallahassee, Florida 32301
Findings Of Fact On a site that would abut St. Johns County on two sides, the City proposes to develop as a landfill about 400 of the 880 acres it owns in the southeast corner of Duval County. The proposed southeast landfill is designed to serve the approximately 300,000 people living in Duval County south and east of the St. Johns River, by receiving 1,700 tons of solid waste a day for ten years, 400 or 500 tons a day more than people in that part of the city now generate. Sandhill and Swamp Scattered over the portion of the property proposed for solid waste deposition are cypress marshes and blackgum sloughs isolated from a swamp and from each other by upland pine plantation and sandhills. Except for some 40 acres cut off from the remainder by a fill road, the hardwood swamp covering approximately 265 acres of the City's property is part of the pristine "Durbin Swamp system which is a major wildlife area, including habitat for threatened and endangered species." T. 2820. Durbin Swamp south of J. Turner Butler Boulevard and east of U.S. Highway 1 is "the most valuable wildlife habitat in the area, maybe in the southeastern United States." T.2921, 3058. The City's consultants characterized 64 of the 123 gopher tortoise burrows they found on some 105 acres in the southern part of the site as active. Sherman's fox squirrels feed and nest on the property. Although "very little of the sand hill habitat [remains] in its natural condition on the property," (T. 185) turkey oak, long leaf pine and sand pine communities do survive. Isolated wetlands scattered through the eastern portion of the site have also been timbered, and ditches intersect many of them. St. Regis Paper Company, who owned the land until earlier this decade, "dug a series of canals . . . to drain . . . part of the land ["it was called upper wetlands"] . . . so that the ground could be high enough to raise good grade pine trees." T. 1417. "The isolated wetlands . . . provide habitat diversity for wildlife, a seasonal source of drinking water, possible refuge during forest fires, as well as breeding and forage locations," (T. 1255) according to the City's draft application. "Wildlife noted on the site includes Florida black bear, white-tailed deer, raccoon, armadillo, cottonmouth, river otter, common night-hawk, alligator, yellow bellied sapsucker, turkey, frog, quail, dove and red- shouldered hawk," (T. 1255) also according to the City's draft application. Bobcats are common. According to the St. Johns River Water Management District's chief environmental specialist, "animals that you would find utilizing the uplands . . . would be a range of small rodents [including] mice, rabbits . . . insects, [mostly tree] frogs, toads, snakes [including] black snakes, rat snakes . . . [o]possums . . . pastorine birds, cardinals, bluejays, blackbirds . . . [and] probably some hogs." T.537-8. Wood storks wade and feed in the isolated wetlands on site. Wood stork rookeries have been found five miles to the southeast and seven miles north of the City's property. Bald eagles nest nearby but off site. Eagles used the now abandoned eagle nest on Eagle Nest Island "three-quarters of a mile from this proposed landfill site," (T. 1419) at least as recently as 1983. One or more eagles still perch on a dead cypress limb on the property (T. 2422), if not elsewhere on site. Ospreys, southeastern American kestrels (T.2918) and six or seven species of woodpeckers, including the rare hairy woodpecker (T2914) have also been seen on site. "There are dirt logging roads just as there are in any property in Florida, but not a great number." T. 2751. "Almost all of the pine flatwoods habitat on the site has been replaced with planted pine." T. 184. The property is comparable to the Wacasassa tract in Gilchrist County which is on the Conservation and Recreational Lands list and under consideration for state acquisition because of its "comparatively unaltered nature." T. 2721. In the past, conservation efforts have brought animals to the property for refuge. T. 1420. Listed Species The Florida Game and Freshwater Fish Commission (Game and Fish) lists the gopher tortoise and the Shermans's fox squirrel, said by one witness to be "imminently threatened," (T. 2899) as species of special concern. T. 2875. A species of special concern "is beginning to show a decline and needs to be . . . considered as a target of conservation and if present conditions continue it's going to be listed as threatened." T.2874. Game and Fish lists the Florida black bear, the southeastern American kestrel and the bald eagle as threatened, the same category in which the United States Fish and Wildlife Service (Fish and Wildlife) lists the American alligator. A threatened species is one destined to become endangered "if present trends continue." T.2874. Both Game and Fish and Fish and Wildlife list the wood stork as endangered, and Fish and wildlife lists the bald eagle as endangered. "An endangered animal is one that under present conditions is in danger of becoming extinct in the near future." T.2874. Listed in the Convention on International Trade of Endangered Species are the bobcat and the river otter. By definition, rare animals are not often seen in the wild. The parties stipulated that the staff of CZR, Inc., a consultant engaged by the City, spent an aggregate of 1400 man-hours on the landfill site, of which 429 man-hours were spent on site for the purpose of performing a wildlife survey. T. 2803. Despite their effort and putative expertise, the City's consultants did not see even a single listed animal. This failure contrasts with sightings by hunters and other experts who spent less time on site, and may be attributable to the time of year (two weeks in the fall) the survey was performed (T. 2425-27, 2893, 2899) or to the way in which it was done, (T. 2429, 3067, 3068) which a wildlife ecologist testified rendered it of "trivial value." T. 3079. The study was expedited in anticipation of a hearing date. T. 2426-27. In any case, the survey does not give reasonable assurance that species whose range includes the City's property are not present in suitable habitat on site. T. 2896-97, 3079-80. This is, indeed, the conclusion the City's own experts reached as regards the gopher tortoise itself, because of the clear sign these creatures' burrows give of their use of the property. Similarly, with respect to the Sherman's fox squirrel, although only a single individual was spotted, distinctive nests and piles of pine bracts on site established their presence. Bear tracks corroborate infrequent sightings on the property, as well as south and east of the site. On a large tract of land to the north, bears are fed daily; three or four feed each day. T. 2421. Alligator sign bore witness to the alligator's use of the property, although the only sighting clearly proven at hearing occurred just across the boundary line. Of course, wildlife does not respect legal boundaries. There is no reason not to believe that the red-cockaded woodpeckers, with six active nests within three miles or the Bachman's sparrows heard singing nearby do not frequent the City's property, which offers suitable habitat for both. It is even possible that the Florida panther, common in the area as recently as 30 years ago, may have roamed the site in more recent years in pursuit of deer or feral hogs. Two witnesses swore they had seen Florida panthers within two miles of the site, one only a few months before the hearing, (T. 1362, 1371, 1419), and a third testified he thought a "cat" he had seen two and a half or three years before the hearing just north of the site was a Florida panther. T.2429-32. The Florida Everglades mink, a threatened species according to Game and Fish, has been spotted at least twice in a cypress bog across the street from the City's property, and probably occurs on the property, as well. Not spotted either on the City's property or on adjacent land, the Florida mouse, the eastern indigo snake and the gopher frog are known to make their homes in gopher tortoise burrows. Of these listed commensal species, the indigo snake is particularly likely to inhabit the site. "The blue indigo snake was turned loose on that property in . . . '81 or '82, since it was an endangered species." T. 1420. The site also affords suitable habitat for the long tailed weasel, under review for listing. Game and Fish has listed the Florida mouse and the gopher as species of special concern. Bachman's sparrow is under review for listing. Fish and wildlife views both the red cockaded woodpecker and the Florida panther as endangered, while Game and Fish views the latter as endangered but the former as threatened only. Aquatic or Wetland Dependent An "aquatic and wetland dependent" species is a species that "requires wetlands or aquatic systems to satisfy some critical biological need in its natural life cycle," (T. 524) apart from simply drinking water. "[W]ithout wetlands or aquatic systems, these species would probably be extirpated from the state." Id. The Sherman's fox squirrel, the gopher tortoise, the Florida mouse, the Florida long-tailed weasel, the southeastern kestrel, and Bachman's sparrow are not aquatic or wetland dependent. Because they use watery environments for feeding, reproduction and other purposes, the alligator, the wood stork (the only stork in North America) and the gopher frog are aquatic and wetland dependent. Because "the whole black bear population in our state seems to shift . . . primarily in the fall and winter months, to the wetlands and . . . eat . . . fruit produced in wetland trees," (T. 527) the black bear is deemed wetland dependent. The indigo snake is also so classified because it "seemed to be heavily dependent upon eating frogs." (T. 526). Even though not wetland dependent "historically and naturally," (T. 527) the "less than probably 100 Florida panthers left in the state" are now so viewed because "they have more or less been restricted to the major swamp systems," id., without which they probably would not survive. The contiguous wetlands on site comprise the headwaters of Durbin Creek, which empties into Julington Creek shortly before Julington Creek reaches the St. Johns River. Large scale residential development of lands lying within the watershed of Durbin and Julington Creeks has been proposed. Durbin Creek and the swamp that gives rise to it serve as a "juvenile fish nursery" (T. 2468) for white shrimp, blue crabs, croaker, anchovies, bream, bass, shellfish, bluegill, and sheepshead. Lower dissolved oxygen levels or other stressors in Durbin Creek would decrease populations in fisheries already at carrying capacity, and already threatened by the prospect of overdevelopment. Dredging and Filling The City intends to build a road running east and west between the landfill site and U.S. Highway 1 following, for the most part, an existing dirt logging road, and crossing Old Kings Road, built in 1765 to connect the capital of colonial Georgia with St. Augustine. Turbidity screens and staked hay bales would be used during road construction to protect adjacent waters. After construction, seeding and mulching would stabilize the sloping shoulders of the fill road. In connection with construction of the access road, plans call for filling wetlands contiguous to Durbin Swamp, 2.8 acres within DER's jurisdiction and 3.5 acres within St. Johns River Water Management District's jurisdiction. Fetterbush, gallberry, scrub palmetto, cinnamon fern, bamboo vine and sphagnum moss grow in these contiguous wetlands, under a canopy of slash pine, loblolly bay, cypress and swamp tupelo. The proposed Class III disposal area would lie two hundred feet north of the south property boundary and 600 feet west of the east boundary. Over significant portions of this 88-acre site, fill dirt is to be used to raise the grade, because the land is so low. Enough fill is to be placed in the marshes and sloughs to avoid depositing solid waste in the water. Trucks would haul fill dirt to the eastern part of the site ("the area starting at the northeast corner of the Class III landfill and extending about 300 feet to the west, starting from a point about midway along the eastern margin of the landfill, and extending about 450 or 60 feet to the west, and along the southern portion of the Class III landfill, about . . . 600 feet" T. 1562) and elsewhere on site, smothering isolated wetlands, where more or less healthy vegetation, generally of the kind found in the contiguous wetlands, now grows. The 132-acre Class I disposal area, which would abut the Class III area on the north, would also cover isolated wetlands now on the site. Together with excavation of associated stormwater retention basins, the disposal areas would disturb a total of 46.3 acres of isolated wetlands within the St. Johns River Water Management District's jurisdiction. The St. Johns River Water Management District originally asserted jurisdiction over 48.5 acres of isolated wetlands, City's Exhibit No. 80, but the objectors offered no evidence that staff's subsequent decision that vegetation on one 2.3-acre parcel did not qualify was erroneous. This total does not include isolated wetlands less than half an acre in extent or isolated wetlands lying both within and without the disposal areas which will cease to function as such when truncated by dredging or filling. In this latter category are some ten acres that will not themselves be dredged or filled. T. 2777-8. St. Johns River Water Management District identified 5.3 acres of high quality isolated wetlands with connections off-site that are to be impacted, City's Exhibit No 80, along with another 11.2 acres of "low quality" isolated wetlands. Id. No stormwater retention basin would intrude into DER's jurisdictional wetlands, but approximately nine tenths of an acre falling within the St. Johns River Water Management District's contiguous wetlands boundary would be devoted to stormwater retention basins. Replacement Wetlands To mitigate the planned filling of contiguous wetlands for construction of the access road, the City proposes "to excavate 3.5 acres of nonjurisdictional pine plantation and create a contiguous swamp wetland." City's Exhibit No. 56. Mature dahoon holly, loblolly bay, cypress and gum trees "will be transplanted from on-site [isolated] wetlands proposed for construction impact." Id. A tree spade is to be used to transplant trees with trunks as much as 12 inches in diameter at "breast height" and up to 50 feet tall, along with existing soils, microbial communities and adjacent understory vegetation. The "physical structure of the trees themselves . . . provide a good deal of the habitat." T. 436. Removing mature trees from isolated wetlands and replanting them in created wetlands would, to some extent, mitigate the loss of perches for bald eagles and other birds. Mature trees in the created wetland would be replanted at a density "approximately half that of existing on-site wetlands to be impacted." Id. Only 80 percent of the replantings are to be replaced, if they die; and then only if it is clear within three years that replacement is needed. A six-inch layer of organic soil, to be spread after the trees have been transplanted, would "provide for growth of herbaceous vegetation." Id. The City would monitor the created wetland (part of mitigation area "A") for three years and transplant additional trees, if needed to assure survival of not less than 80 percent of the number of trees originally planted. Of these 3.5 acres, the City has identified 2.8 as specifically intended to mitigate the filling of wetlands within DER's jurisdiction. With respect at least to this portion, the created wetland "will function probably much the same as the 2.8 acres" (T. 2765) to be filled in constructing the access road and "would compensate for the" (T.2765) attendant loss of vegetation. In transplanting mature hardwoods, "[i]t's sort of a physical impossibility to get all the root material . . . [and y]ou also get some loss of branches, limbs and stems just from the physical movement of the tree." T. 2482-83. One reason a wetland "system stays wet . . . is a thick canopy." T.2486. With more sunlight streaming through a sparser canopy, the "vegetation is not going to be the same." T. 2487. "[B]ecause you don't expect the wetlands to function as well as the original wetlands you're replacing, there is a general rule of thumb that . . . you create twice as much wetlands as the wetlands you've destroyed." T. 2488. "A three-to-one ratio would not be unusual for a good mature forested hardwood system." T.467. St. Johns River Water Management District's Applicant's Handbook calls for a ratio between 2:1 and 5:1, but states: "The ratios may also be adjusted when wetlands creation is combined with wetland mitigation proposals such as an open buffer area adjacent to the wetlands, conservation easement, wetland enhancement proposals or alternative mitigation proposals." T. 504. The ratio proposed here is less than one to one. In all, mitigation area A would comprise 11.0 acres of what is now pine plantation. Aside from a .55 acre pond in the middle, mitigation area A would consist of wetlands contiguous to existing wetlands on which three different, if related, vegetative communities are to be planted. In addition, the City proposes to create three different isolated wetland areas, one of which (mitigation area D) it characterizes as "high quality." Six acres of what is now pine plantation would be excavated on the north edge of the property. Using the same, experimental techniques proposed for mitigation area A, cypress trees would be placed on 3.4 acres, and 2.6 acres would be devoted to a combination of loblolly, cypress and dahoon holly. Another 9.8 acres of isolated wetlands would be created within borrow pits, 6.8 acres in borrow area No. 1 (mitigation area B) which would include .55 acres of open water, and 3.0 acres in borrow area No. 2 (mitigation area E.) Just north and east of the truck scales, mitigation area B would receive 200 adult trees per acre planted to the extent they are available on site, or 400 trees per acre planted with nursery stock. The same density is planned for mitigation area E, to be located across the road from stormwater retention basin 4. The City also proposes to remove a segment of a logging road built on fill that now cuts off 40 acres from the remainder of Durbin Creek Swamp. Removal of the fill and revegetation would not only increase the extent of the swamp by 0.3 acres, it would restore historic sheet flow in that part of the swamp. Finally, the City proposes to spread muck, if available, over the shallow, southern part of stormwater retention basin 2 and plant 12 acres of grass ("[w]etland herbaceous species" City's Exhibit No. 80) which, however, the City reserves the right to dredge up "from time to time". Id. p.13. Other Effects, Other Mitigation Building and operating the landfill on the site proposed would displace upland wildlife and fragment largely undisturbed and undeveloped wildlife habitat. Fences along the northern, eastern and southern site boundaries would present a physical barrier. Human activity, particularly daytime traffic on the access road, would also create a "bio-geographical barrier." Developing a landfill at the edge of the swamp amounts to "leapfrogging," instead of expanding existing pockets of industrial or other development. A witness characterized the area to the south of the site as "rural developed"; some 164 people live within a mile of the center of the site. T. 78. But private ranch lands to the north, like undeveloped land to the east, afford good wildlife habitat. Habitat fragmentation divides and isolates animal populations. "Fragmented populations are more susceptible to disease, inbreeding and with time, poaching." T. 2890. The landfill would displace gopher tortoises, their commensals, if any, and other wildlife using sandhill or pine plantation habitat, as well as wildife, including wood storks and other migratory birds, making use of the isolated wetlands that are to be filled over. With the filling of isolated wetlands, migratory birds would lose holly berries and other forage. Filling or excavating acreage at the periphery of the swamp would also destroy habitat and displace wildlife. Wildlife now on site reaching suitable habitat elsewhere will have to compete for limited space against animals that have already established territories. The result should be a net decline in populations. T.2898. Increasingly sequestered, the Durbin Swamp system is already under pressure from urbanization to the north. For animals that remained in the vicinity, development of the landfill would occasion other difficulties. But evidence that landfill noises and odors "would have no discernible impacts to the value of wetlands as habitats for aquatic and wetland dependent species" (T. 528) went unrebutted. A buffer of at least 50 feet would separate contiguous wetlands from stormwater basins and other construction, but this is considerably less than the 528 feet Dr. Harris testified was necessary to avoid "greatly erod[ing] the native faunal diversity of the Durbin Swamp wildlife." T.3073-74. Placement of the landfill on this site would increase the numbers of a half dozen "middle-sized mammal omnivores" (T. 3078) so that gopher tortoises, turkey, quail, "anything that nests on the ground will be subject to the plundering by the enhanced population of raccoons, opossums, gray foxes, red foxes . . . and such." T. 3079. Increased numbers of armadillos would also pose a heightened threat to animals that nest on the ground. Landfill operations can be expected to attract seagulls and birds of other species, including nest predators and the brown-headed cowbird, which takes over other birds' nests to lay its own eggs (T. 3071-2) and would pose a particular threat to Swainson's warbler. It is not clear that any of the mitigation areas the City proposes is intended to replace wood stork feeding habitat that would be lost to dredging and filling. Wood storks feed on dense fish populations in shallow water, when receding water levels make the fish easier to catch. Isolated wetlands on site that have served this function would be lost (T. 2419), although not all of the isolated wetlands to be lost have enough water to support the kind of fish on which wood storks prey. The deep, steep-sided ponds planned for the mitigation areas do not replicate the necessary conditions. Whether birds may safely feed in or drink from untreated stormwater run-off in shallow portions of the retention basins is doubtful. When it rains, particularly the initial flush of run-off would deliver pollutants, including oil, greases and gasoline left by garbage trucks, to the retention basins. T. 1820-1. Removing the fill road and restoring normal flows to the 40-acre patch of the swamp on the other side, as the City proposes, would not add to feeding areas available to wood storks, except for the 0.3-acre roadway itself. The project would disrupt "very superior black bear habitat." T. 3059. Tending to avoid human activity, bears would likely range further east, foregoing foodgathering on site. On the other hand, food or other refuse brought to the landfill might lure bears to their deaths, intentional or accidental. "[C]ollisions with human vehicles," (T. 3062) is the chief cause of black bear mortality in Florida. Bears have been killed in this fashion within a mile of the site, (T. 351 1411-4, 2438) although not during daylight hours when the landfill would be in operation and garbage trucks would travel the access road. Creation of wetlands will not mitigate destruction of upland habitat. On the contrary, additional upland would be taken to create the wetland mitigation areas planned. But the City proposes to give a conservation easement on 129 acres of upland, adjacent to the swamp, that is to remain undeveloped. The upland easement would preclude a host of uses inimical to wildlife, and would mitigate to some extent the loss of wetland habitat for animals which use both uplands and wetlands, like the black bear, even though cut over slash pine plantation is among the very least important or productive wildlife habitats in Florida. The easement would not include sandhill habitat. The City has also undertaken to give a conservation easement covering some 260 acres of wetlands contiguous with Durbin Creek Swamp. This would not, of course, increase the extent of existing wetlands, but it would add a measure of protection for those that survived the project. Perhaps most importantly the wetland conservation easement would preclude expansion of the landfill further into the wetlands, as long as it remained in force. Existing regulatory restrictions on the use of wetlands prevent many uses, even without an easement. Apparently no regulation precludes harvesting bottomland hardwoods, however, so long as no excavation is involved, and vegetation, once severed, is not redeposited on site. But converting deforested areas to pinelands, without a permit from the Army Corps of Engineers would probably not be authorized, under 33 U.S.C. s.1344 (f)(2). See Avoyelles Sportmen's League, Inc. v. Marsh, 715 F.2d 897 (5th Cir. 1983). The City proposes to relocate gopher tortoises and any indigo snakes, gopher frogs or Florida mice that can be found to an unspecified new home off- site. Survival rates for gopher tortoises after similar relocations in the past have ranged between 30 and 100 per cent. By the year 2,000, the St. Johns County gopher tortoise population is predicted to fall by 90 percent, and Duval County is predicted to be devoid of gopher tortoises, even without relocation efforts of the kind proposed. Some or all of the gopher tortoises slated for removal may be descended from those who were brought to the site from Lake City. Perhaps even some who started out in Lake City would themselves make this second exodus to a new promised land. Stormwater Management The site proposed for the southeast landfill does not lie within a basin for which the St. Johns River Water Management District has adopted volumetric requirements. A "set of double [triple (T.1740)] box culverts five feet by eight feet . . . and . . . four other," (T. 425-6), "equalizer culverts," large enough for bears to move through (T. 415) would convey preexisting surface flows. A cross drain in the vicinity of the service plaza would serve the same function. Flood elevations would not increase more than a foot immediately upstream or more than 0.1 feet 500 feet upstream. The access road would not impound surface waters. Exfiltration trenches paralleling the access road "designed based on South Florida's criteria" (T. 1737) would filter contaminants from water running off the road. Within 72 hours of a 24-hour, 25-year return storm, the exfiltration system would be able to treat twice the volume of stormwater that recurrence of such a storm would generate. T. 1743. The scale plaza area where garbage trucks moving east on the access road would be weighed before being directed further down the road to a disposal area, is to be built on an upland portion of the property, and with it a wet detention pond to which surface water from the plaza and associated roadway would drain. Swales and berms would divert surface flow from undeveloped parts of the property that might otherwise reach the detention pond. The interceptor ditch and associated works would reduce by 2.5 hours the time of concentration for runoff from a 202-acre watershed, but cause no other changes in watershed characteristics. A weir would make it possible to regulate overflows and allow detention of run off long enough for biological assimilation of most pollutants. For the 25 year return, 24-hour storm, the pre-development peak rate of discharge (6.3 cubic feet per second) is less than the post-development peak rate without detention (18.4 cubic feet per second) but more than the post- development peak rate of discharge with detention: 3.9 cubic feet per second. An orifice below the weir, with a diameter of 1.5 inches, is designed to discharge less than half the treatment volume (22,088 cubic feet or 2.5 inches times the impervious portion of the area drained) in 64.21 hours. The design meets DER and St. Johns River Water Management District criteria. Portions of stormwater retention basins 1 and 2, situated north of the disposal areas, would lie within the 100-year flood plain. These two retention basins are designed to receive stormwater running off the Class I site or diverted around the site, as is stormwater retention basin 3, while stormwater retention basin 4 is intended to collect stormwater flowing off or around the Class III disposal area. Stormwater retention basins 3 and 4, like the southern area of stormwater retention basin 2, are not to be excavated to a depth of more than five feet below grade, to prevent groundwater from seeping into stormwater retention basins, dewatering the wetlands where it would otherwise emerge. With terraces at 20-foot intervals, to a height of 60 feet above grade for the Class I site and 40 feet above grade for the Class III site, both landfills would resemble Mayan temples, at build out. Ditches around the perimeter of each terrace are designed to convey stormwater to slope drains which would bear water to the level below, eventually to the perimeter ditch on grade, from which it would flow, through box culverts under roads built around the landfill, into the retention ponds. To the extent necessary to prevent groundwater infiltration, the ditches are to be lined. Stormwater retention basin 2 has two discharge structures, while each other basin has a single discharge structure leading to a ditch that would convey stormwater to Durbin Swamp. Perforated pipes, swathed in filter cloth, would be buried under highly permeable sand, along the sides of the retention ponds. Installed above seasonal low groundwater elevations, in order to avoid draining groundwater from the area around the ponds, during dry seasons, (T. 1781) they would have to go below seasonal high groundwater elevations, in order to be low enough to serve as drains for the retention ponds. Ambient groundwater would seep into the pipes, whenever groundwater levels outside the ponds rose above the pipes' elevation. But the pipes would still be able to drain the retention ponds, because of the relatively greater (vis-a-vis soils on site) hydraulic conductivity of the highly permeable sand to be trucked in for use as a filter medium. In time, these side drains or underdrains would clog and require expensive maintenance. But, assuming proper maintenance of the retention pond drains and of the drains that make up the roadway exfiltration system, the landfill and associated development would not flood or dewater wetlands that are not themselves to be dredged or filled. Except what is lost to evaporation, water entering the retention ponds would reach the wetlands, whether through the underdrains, over the weirs and through the conveyance ditches, or by movement underground after seeping through the bottom of the basin. The post-development peak rate of discharge from the area draining into the stormwater retention basins should not exceed pre-development rates for a 24-hour 100 year return storm or any lesser event. Because of roads and other impervious surfaces, a greater volume of surface water should reach the wetlands, causing stages about two inches higher than under pre-development conditions in "a typical summer thunderstorm." T.1782-3. The increase in surface flow corresponds to a decrease in water percolating down into the groundwater, and may result in additional loss to evaporation of water that would otherwise reach wetlands. But any such effect will be slight; surface and groundwater levels and surface water flows will not be adversely affected. T. 1783. Nor will existing surface water storage capabilities be adversely affected, despite the placement of portions of retention basins 1 and 2 within the 100-year flood plain. This encroachment at the very edge of the flood plain would rarely have any effect on surface water flows. Almost all development is to occur outside the ten-year flood plain. The stormwater basins could hold an inch of runoff without discharging water over the weirs. The underdrains, which would, when originally installed, have a hydraulic conductivity of about 130 feet per day, could remove an inch of run-off within approximately 40 hours. On the conservative assumptions that half of a two-foot vadose zone would already be saturated at the time a 24-hour, 25-year return storm dropped an additional 8.9 inches of rain on site, and that soils on site have a porosity of .5, the retention ponds could contain the resultant run-off for treatment, before discharging it first through weirs then through the underdrains. Three surface water monitoring stations are planned. One upstream would make it possible to assess background conditions. Another at the point of discharge from stormwater retention pond 2 would reveal whether the retention ponds and their sidedrains were functioning as intended. A third monitoring station in the southwest corner of the site should give similar information as to the roadside exfiltration system. Hydrogeology Except in the southeastern corner of the City's property, where the ground slopes down to the east, the land the City owns, like the adjacent land to the south owned by the McCormicks, slopes down in a more or less northwesterly direction, falling from 55 feet NGVD on the southern boundary to 15 feet NGVD at the northwest boundary, which intersects an elbow of the swamp. Although groundwater flows east of north under the southeast corner of the property, the flow under the property is generally northwesterly, following the topography. Class II groundwater in the surficial aquifer underlies the property at depths ranging "from almost to land surface to five or 10 feet below." (T. 1517). City's Exhibit No. 161. Groundwater flowing northwesterly crops out in isolated wetlands, evaporates, transpires or discharges into the swamp. To assure that the bottom of each exceeds seasonal high groundwater levels, measured in February of 1987, by the number of inches a 24-hour 25-year return storm would add, fill would be placed under both disposal areas, as needed. Because the Class I solid waste disposal site is to be lined, recharge by rainfall would be precluded there. With a liner intercepting percolating rainwater, groundwater would not attain predevelopment levels. The depression thus induced under the Class I site would more than offset the tendency groundwater under the Class III site would otherwise have to mound up into the bottom layers of solid waste deposited there. Recharge from rainfall (become leachate) would continue at the unlined Class III site; the height of accumulated waste would slow or stop evapotranspiration offsetting percolation there. But groundwater would flow down steeper gradients to lower levels underneath the Class I site (which lies between the Class III site and the wetlands where groundwater discharges) rather than rising into waste disposed of on the Class III site. The horizontal component of flow would continue to exceed the vertical component by several orders of magnitude. Beneath the surficial aquifer, which extends to depths of 50 to 100 feet below ground and consists of sand interspersed with a "matrix of soil, organic materials, clays and silts . . . little layers of clay and hardpan" (T. 1517) lies a continuous, confining layer of gray, sandy material with gravel and shell fragments, 12 to 40 feet thick, blanketing the undulating surface of the Hawthorne formation underneath. "[S]ome 40 percent of the material comprising the Hawthorne formation in this area is clay and the remainder is a mix of sands, silt stone, shell beds and phosphatic sands." (T. 1526) This assures that rainfall or other fluids percolating into the surficial aquifer on site will move horizontally downgradiant, reentering the atmosphere or discharging to the surface, rather than penetrating the thinner aquitard above the Hawthorne formation and sinking another 250 feet or more through the Hawthorne formation itself into the Ocala group and Floridan aquifer below. No subterranean feature in the vicinity permits water in the surficial aquifer to reach the Floridan. No peat, muck or other unstable soils underlie the site. Under 3,000 pounds per square inch, the maximum load anticipated, the ground is not expected to settle more than one inch. The addition of fill dirt does not alter this estimate significantly. Disposal Design The Class III disposal area would not have a liner, a leachate collection system or gas controls. After travelling through soils under the site, leachate from the Class III site would enter the groundwater. The City proposes to train and direct staff, to the end that only yard trash and construction and demolition debris end up in the Class III disposal area, where waste would be deposited directly on fill dirt or naturally occurring soils. No solid waste is to be disposed of within 200 feet of wetlands contiguous to Durbin Swamp lying within DER's jurisdiction. A composite liner of the kind in place at Alachua County's southeast landfill would form the corrugated bottom of the Class I landfill: a 60 mil high density polyethelene layer overlying two six-inch lifts of calcium montmorillonite, a clayey sand that is to be placed on compacted subgrade configured in "a herringbone design with peaks and valleys." T.765 Separating trenches in the valleys, sloping ground would rise, then fall at least two feet for every hundred horizontal feet. Steps would be taken to remove rocks, twigs, roots and the like, before compacting subsoils on site. A machine called a sheepsfoot is to be deployed, once half the montmorillonite has been put down, to pulverize clods and mix the material, in an attempt to assure uniformity within each lift of clayey sand. Other machines would compact each lift to a specified Proctor density. These efforts would not succeed in eliminating all clods or other imperfections, and the sheepsfoot would mix subgrade with the bottom layer of montmorillonite, introducing new impurities. Soils on site have hydraulic conductivity ranging from 1 x 10-3 to 1 x 10-4 centimeters per second. Clayey sand is also subject to desiccation cracking; as it dries out, large cracks appear. On top of this kneaded, compacted and finished 12-inch layer of clayey sand, once it had been inspected to assure the absence of roots, rocks, sticks, glass or other sharp objects, a specialty contractor would unroll strips of unreinforced high density polyethylene. After arranging the panels to minimize seams in the leachate collection trenches, technicians would weld the polyethylene strips to one another. An independent, third-party quality assurance contractor would inspect and test the seams before the synthetic liner was finally positioned, and as flush a fit as possible was achieved. Both the high density polyethylene and the quality assurance program are to meet the requirements of NSF Standard 54 and EPA Publication SW-870, March, 1983. Some wrinkling and occasional flaws in the plastic liner are inevitable. Wrinkling causes ponding, not only of rainwater during construction, but also of leachate, once the landfill is in operation. Tire tracks or other indentations in the montmorillonite layer can also cause ponding. In time, under the growing weight of solid waste, and with heat that biodegradation of the waste would generate, some of the wrinkles might subside, but the liner might also sink into additional depressions. Careful construction could keep ponding to a depth of little more than an inch. T. 2971, 2979. Extrusion welds (when done properly) render the seams stronger than the panels they join. But even if "you are really, really good" (T. 2957) and even when you're careful you get an occasional problem, one or two per acre, no matter how careful you are. And if you're not as careful, you get more, typically something on the order of five holes per acre. T. 2967 Carelessness on one project resulted in as many as 60 flaws per acre. Nondestructive testing methods do not detect all defective welds. T. 2966. Defects may develop after the plastic liner has been inspected. Stress on high density polyethylene associated with "conform[ing] itself to whatever is underneath it" (T. 2962) concentrates in scratches, gouges and crimps to cause "as much as 30 percent" (T. 2964) of the holes in the material. "[T]here is no shortage of scratches on a construction site." T. 2962. Leachate Collection Another high density polyethylene geotextile, chosen for its transmissivity (the geonet), is to be placed on top of the high density polyethylene liner (the geomembrane), where it would act as a synthetic drainage medium. In order to prevent overlying sand's clogging the geonet, compromising its ability to conduct leachate down into the trenches, a third, highly permeable geotextile, "a non-woven needle punched type" (T. 637) (the geofilter) would go directly on top of the geonet. The twelve-inch sand drainage layer blanketing the geofilter would have hydraulic conductivity of 1 x 10-3 centimeters per second, if sufficient quantities of suitable sand could be obtained. (T. 764) Another 12 inches of native soil is to cover the sand drainage layer. While the geofilter and the soil layers above it would parallel the landfill liner on the slopes between trenches, they would form arches over the trenches themselves. Continuing to follow the contours of the montmorillonite, the geomembrane and the geonet would line the trench bottoms. Below these arches, inert drain field rock would fill the lined trenches, supporting one perforated PVC pipe eight inches in diameter in each trench. The Class I landfill is to be built in fourteen 250-foot wide cells, with each cell having two leachate collection pipes on 125-foot centers. Manholes at either end of each leachate collection pipe would allow access, in case unclogging the pipe proved necessary. Longitudinally, the trenches would slope to the north, falling two to 20 feet for every 1,000 horizontal feet. Leachate reaching the trenches would flow along the trench bottoms (or through the pipes) to the manholes on the northern boundary. Also to be made of leachate-impervious PVC, leachate drain pipes, which would not be perforated, would connect all manholes on the northern perimeter. Varying in diameter from eight to twenty inches, depending on the number of manholes they were designed to empty, they would converge at a leachate pumping station north of the perimeter road. T. 590-1. A rupture in one of the single-walled leachate drain pipes could spill massive quantities of leachate on naturally occurring soils. Leachate which reaches the station is to be pumped into a 12,000 gallon storage tank nearby. To be mounted on a concrete slab surrounded by a curb high enough to contain all 12,000 gallons, if the tank failed, the tank would be constructed of high density polyethylene. The plan is to pump leachate from the tank through a four-inch discharge pipe into tanker trucks which would take the leachate to the Buckman wastewater treatment plan for disposal there. During "the maximum leachate production period, when you have 10 cells open," (T.687) an average of 35,000 gallons of leachate a day would require removal for disposal in this fashion. Additional tanks could be built. As a precaution, isolation valves would permit cutting off all flow of leachate to the pump station. In addition, isolation valves would allow cutting off the flow from any of seven pairs of cells (or slowing the flow from all, T. 705) in the event of an abnormal circumstance where leachate production in the facility exceeds the hydraulic capacity of [the] leachate removal system, the pumping station and storage tank and the tanker truck system. T. 591. Isolation berms separate each pair of cells susceptible to being put to use as temporary storage for leachate. The leachate drain pipes themselves afford more than 23,000 gallons of emergency storage. T.703. Ventilation As they decompose, materials to be deposited in the Class I landfill produce methane gas, carbon dioxide, and other, malodorous gases. Collection pipes with eight-inch diameters, running horizontally on 150-foot centers in the second and fifth lifts would allow gas to escape at either end, on the north and south sides of the landfill. This would prevent methane's building up and exploding or catching fire. By assuring their gradual release, it should also minimize the impact of foul smelling gases, which, in any event, are generally undetectable at a distance of more than 1,000 feet. But specific condition eight of the proposed landfill permit requires that the passive system be converted to an active system, if necessary, using vacuum suction and flaring. GIGO Although there "is not much industry in the southeast portion of Duval County," (T. 953) sewage sludges and other industrial wastes "except any hazardous waste as defined in the Federal Register" (T. 947) would be accepted for disposal at the Class I facility, if properly manifested. The proposed southeast landfill would receive waste that would otherwise have gone to the unlined east landfill. Household waste contains toxic materials. Tests of leachate generated in other lined landfills from which hazardous wastes are excluded have demonstrated the presence of some 30 metals and 56 organic compounds. City's Exhibit No. 89. Rainfall percolating through (and moisture already present in) waste deposited at the proposed Class I facility can be expected to leach the same array of substances from materials deposited there. Judging from experience elsewhere, leachate from the Class I facility would contain 13 or 14 (if 4-methyl phenol is included) substances in concentrations in excess of governmental standards or health-based criteria identified by a toxicologist engaged by the City. City's Exhibit No. 90. Among these would be methylene chloride, trichloroethylene, tetrachloroethylene and benzene, (T. 1478) as to which "the current regulatory policy is that it is possible for as little as one molecule . . . to act as . . . a carcinogenic initiator . . . [so] that there is no real threshold." T. 1447. Maximum concentrations would exceed those Florida prescribes as primary drinking water standards for titanium threefold, for benzene fivefold, for chromium more than fivefold, for sodium approximately 16-fold, for manganese 68- fold, for iron 280-fold, and for methyl ethyl ketone almost 130-fold. City's Exhibit No. 90. Methylene chloride would occur in the leachate in concentrations 39 times greater than the "USEPA proposed Preliminary Protective Concentration Limits." Id. Only yard trash "soils/land clearing waste, waste from landscapers" (T.956) and construction and demolition debris, "clean debris, inert materials, construction and demolition wastes that are inert, roofing materials," id., and the like, not mixed either with industrial or with regular household garbage, would be accepted for disposal in the Class III facility. Unless these materials are adulterated, they are "easy to bio-degrade . . . [or] are insoluble," (T. 1923) and rainwater percolating through them should yield a leachate with "neutral pH . . . low to moderate [biological oxygen demand] . . . [and] metals [if any] . . . below detection limits or background conditions." T.1923. But "some materials get in" (T. 2106) despite efforts to exclude them. "Demolition debris can have oiled floors and creosoted pilings as part and parcel of the structure." T. 3008. Old paint contains lead and cadmium. Debris from old houses can include rat poisons. Grass clippings "could contain small amounts of herbicides and pesticides." T.2101. In fact, "it's not unusual for yard waste to be very rich in biocides." T. 3009. Such chemicals are used in Jacksonville. When autopsies of seagulls found at the Girvin Road landfill revealed traces of diazanon, tests of water taken from "the stormwater ponds in the subdivision across the street" (T.990) showed diazanon was present there. Bioassays the DER runs on effluent from the City's Buckman wastewater treatment plant regularly report toxicity in excess of allowable limits (T.1877-8) and the EPA has "identified malathion and diazanon as the toxicants," (T. 1881) which are killing at least one species of flea in certain standard laboratory tests performed on the effluent. Leachate Leakage The composite liner would not keep all leachate generated in the Class I landfill from reaching the naturally occurring soils underneath, and eventually the groundwater under the site. Even under normal operating conditions, and even on the City's optimistic assumption that it can achieve a permeability of 1 x 10-7 centimeters per second, thousands of gallons of leachate a year would escape through flaws in the liner while the landfill was in operation. If leachate drain pipes burst or torrential rains required backing leachate up in the cells, thousands of gallons a day could leak. If two lifts of clayey sand achieve a permeability no lower than 1 x 10-5 centimeters per second, millions of gallons of leachate would enter the groundwater over the ten-year active life of the landfill, even without burst pipes or extraordinary precipitation. Once the Class I landfill attained the design height, it would be capped with impermeable materials to minimize leachate generation. As with the liner underneath, the impermeable cap would be covered with sand to facilitate drainage. Vegetation would hold the drainage soil in place. Closure plans have already been drawn, but they are subject to revision and require DER approval before implementation. If necessary, side slopes could be lined to prevent leachate seepage there. Closure would reduce, but would not end, leachate production and leakage. Virtually impermeable to water, high density polyethylene is highly permeable to certain permeants, including some that occur in landfill leachate. Leachate constituents known as "aromatic hydrocarbons" move "right on through" (T. 3017) high density polyethylene. To some extent, the montmorillonite component of the liner under the Class I area would impede these materials' movement into naturally occurring soils. The evidence did not quantify the montmorillonite's efficacy in this regard, but the City's expert's testimony that leakage of this kind would be "insignificant" (T. 830) went unrebutted. Permeation aside, the rate at which leachate leaks depends on the nature, number and size of flaws in the synthetic liner, the height and duration of the leachate head above the defects, and the transmissivity of what is underneath. Here transmissivity turns both on the hydraulic conductivity of the clayey sand in the vicinity and on the extent of air spaces between the clayey sand and the overlying high density polyethylene. Sand grains cause microscopic spaces, while imperfections in the montmorillonite layer and wrinkling of the polyethylene cause larger spaces. Leachate leaking into a space between the geomembrane and the soil spreads over a larger area before penetrating the clayey soil, in correspondingly larger volumes. Calculations predicated on the transmissivity characteristics of the geonet and the sand layer above it demonstrate a theoretical leachate flow over the liner so rapid that leachate would never accumulate on the geomembrane to a depth of as much as a tenth of an inch. But these calculations assume no ponding behind wrinkles in the synthetic liner, or any other impediment to the flow of leachate. Especially since holes in liners are likely to occur near wrinkles (because stresses are greater there) a more realistic assumption, for calculating leachate leakage rates, is a head of one inch, "the smallest practical hydraulic head you can achieve." T. 2994. On the twelfth day of hearing, when St. Johns County's liner expert testified that a six-inch layer of the montmorillonite might result in permeability as high as 5 x 10-4 centimeters per second, the City had not yet amended its application to increase the thickness of the clayey sand layer from six inches to twelve. The City's proposal now calls for two lifts of a 20 percent clayey sand with a saturated hydraulic conductivity in situ of 1 x 10-7 centimeters per second. This can be achieved, if at all, only with material that laboratory tests indicate has hydraulic conductivity of 1 x 10-9 centimeters per second or less. "[I]f you put down clay that the lab says has a permeability of 10 to the minus 7 centimeters per second, . . . when you put it down in the field you get from one to two orders of magnitude greater permeability than that. . . . related to how thick it is." T. 2988. Even a three-foot liner comprised of six lifts ends up with conductivity ten times greater than the same material under laboratory conditions. Mr. Deans, who designed the liner for the City, testified that a permeability of 1 x 10-7 centimeters per second was "readily achievable" even with six inches of clayey sand, but he had never designed a liner before, and his testimony in this regard has not been credited. To judge from its eleventh- hour amendment, the City did not believe it, either. Only two lifts are to comprise the clayey sand layer. No study of a clayey sand layer as thin as 12 inches has found hydraulic conductivity of less than 1 x 10-5 centimeters per second. Three lifts are necessary to create an effective barrier. "[Y]ou need at least three lifts to get the middle one hopefully working right." T. 2987. "[E]ngineers believe that the bottom layer gets fouled, the top layer cracks and has problems. Your best chance is the in between layers. You need at least three layers, and they would rather have four to be reasonable, and EPA says six." Id. Studies of twelve-inch liners put down in two lifts ("[t]he thinnest one we found anybody had ever studied" T. 2980) showed them to be "inadequate." T. 2987. With an inch of head, assuming defects with an average area of 1 x 10-5 square meters, an assumption with which all the experts seemed comfortable (the City's expert assumed larger holes), the published EPA formula yields a per defect leakage rate of 6.7598 x 10-11 cubic meters per second, assuming hydraulic conductivity for the montmorillonite layer of 1 x 10-7 centimeters per second. But plans to use only two lifts to form a 12-inch layer do not give reasonable assurance of vertical hydraulic conductivity that low. Mr. Coram's testimony to the contrary, expressly predicated on reports of laboratory tests on samples, did not address the evidence that laboratory tests do not tell the whole story, in the case of a thin layer of clayey sand compromised not only by inherent imperfections, but also by highly permeable subgrade soils, kneaded into it by the sheepsfoot. Because "clods are broken down in the laboratory and stones and cobbles are screened from the sample . . . the effects of both are not accounted for in permeability tests on laboratory compacted samples." City's Exhibit No. 190. Substituting a hydraulic conductivity of 1 x 10-5 centimeters per second, the EPA formula yields a leakage rate between 57 and 58 times greater: 3.8898 x 10-9 cubic meters per second. Although the EPA's most recently published leak rate formula makes no allowance for less than an ideal fit between the components of a composite liner, City's Exhibit No. 190, the author of the EPA formula, who testified for St. Johns County, subscribed to modifications to the formula developed to take this factor into account. DER's Exhibit No. 35. The montmorillonite layer's hydraulic conductivity is an unrealistically low measure of the transmissivity of the medium underneath the polyethylene. Using it for this purpose, without adjustment, ignores inevitable, intervening air spaces. Perfect contact between a synthetic liner and the soil it overlies cannot be accomplished, even in a laboratory setting. On a project of the kind proposed, contact would range from good, where the relatively larger size of sand grains in the clayey mix creates air spaces, to poor, where wrinkles (left in to avoid the weakening effects of stretching the material) cause much larger air spaces. No expert found fault with the more recent formulae (Bonaparte/Giroud) set out in DER's Exhibit No. 35, and none quarreled with the proposition that the published EPA formula made unrealistic assumptions about the contact between polyethylene and clayey sand. The Bonaparte/Giroud formula that assumes good contact yields a leakage rate of 1.6090 x 10-8 cubic meters per second per defect, a little more than four times what the EPA formula predicts for an ideal fit, assuming an inch of head and vertical hydraulic conductivity for montmorillonite in situ of 1 x 10-5 centimeters per second. Assuming poor contact, without varying any other assumptions, yields a leakage rate approximately 5.5 times greater: 8.8115 x 10-8 cubic meters per second. In its proposed recommended order, at page 35, DER accepts, at least for purposes of argument, the proposition that contact between soil and geomembrane would be poor in places, and calculates a leachate leakage rate of 5.45 x 10-3 gallons per day (2.3887 x 10-10 cubic meters per second per defect.) But this assumes that "the permeability of the City's clay liner will be 1 x 10- 7 cm per second and the maximum head over liner will be 0.062 inches." The evidence showed that the maximum head could not be kept below one inch, and did not give reasonable assurances that two lifts would result in vertical hydraulic conductivity of 1 x 10-7 centimeters per second for the clayey layer. Substituting an inch for .062 inches gives a rate of 2.9177 x 10-9 cubic meters per second. Substituting 1 x 10-6 for 1 x 10-7 and an inch for 0.062 inches, the leakage rate becomes 1.6034 x 10-8 cubic meters per second. Groundwater Contamination Uncontroverted expert opinion put the flow of groundwater under the Class I disposal area at 0.063 cubic feet or 0.47 gallons per day (2.0592 x 10-8 cubic meters per second) through a hypothetical square or cube one foot on a side. Except under unusual conditions, leachate leaking from the Class I facility would, before entering the groundwater, pass through approximately a foot of fill dirt or naturally occurring soils, which consist in large part (92 to 99 percent) of relatively inert, quartz sand. The presence of organic materials, however small the quantities, raises the prospect of adsorption and other chemical reactions, before steady state is attained. Physically, the soil would disperse the leachate, diminishing concentrations of leachate constituents entering groundwater. After such attenuation as the soil afforded, leachate would enter the groundwater, which would dilute and further disperse it, although not nearly as dramatically as the City's toxicologist testified. This witness assumed uniform mixing, rather than the discrete plume which persons with greater expertise in groundwater contamination convincingly predicted. By using the rate of "groundwater flow beneath a defect and the rate of leakage through that defect . . . [he] c[a]me up with a volume to volume dilution factor to identify a concentration in the groundwater." T. 1214. Because Dr. Jones took an unrealistically low leakage rate as a starting point, he predicted an unrealistically low concentration of one part leachate to 4,400 parts groundwater, inside a cubic foot immediately below each leak. Concentrations vary directly with the leakage rate per defect. T. 1224. The formula that assumes good, but not ideal, contact between liner components yields a leakage rate per defect of 1.609 x 10-8 cubic meters per second, if the layer of clayey sand has hydraulic conductivity of 1 x 10-5 centimeters per second. Substituting this leakage rate, the City witness' methodology yields a dilution ratio of 2.0592 parts groundwater to 1.609 parts leachate, or 1.2798:1, more than a hundred times less than the 130:1 dilution ratio that the City concedes is the minimum it must prove, at the edge of the zone of discharge. See Respondent City of Jacksonville's Motion to Strike St. Johns County's Memorandum Concerning Leachate Rates, p. 5. Substituting the coefficient for poor contact, the ratio in the hypothetical cube under the landfill becomes a paltry 2.0592 parts groundwater to 8.8115 parts leachate or .2337:1. Using Dr. Jones' methodology, a leakage rate of 1.6034 x 10-8 cubic meters per second per defect would result in leachate concentrations in groundwater of one part leachate to 1.2483 parts groundwater. Substituting a rate of 2.9177 x 10-9 cubic meters per second per defect yields a ratio of 2.0592 parts groundwater to .29177 parts leachate, or one part leachate to 7.0576 parts ground water. Even if the contact between geomembrane and montmorillonite were uniformly good and the clayey sand layer had a permeability of 1 x 10-7 centimeters per second at every point, a dilution ratio of only 37.4444:1 would result. In 132 acres of high density polyethylene, the evidence showed that 660 flaws could reasonably be anticipated, and that 132 flaws were absolutely unavoidable. Methylene chloride would end up in the groundwater in proscribed, carcinogenic concentrations as far away as 20 feet from many leaks within 90 days. Under some leaks, perhaps all, benzene, a proven human carcinogen, would also occur in prohibited concentrations. As leachate plumes dispersed, concentrations would diminish, eventually to levels at which they pose "potentially acceptable" (T. 1475) risks even in the case of "a 70-year water consumption of two liters of water per day by a 70-kilogram adult." T. 1217. No evidence suggested that they would remain in concentrations above these levels by the time they reached the edge of the zone of discharge. City's Exhibit No. 193, which uses a leakage rate much lower than the range of leakage rates likely to occur, if the landfill is built, predicts concentrations of various leachate constituents at the edge of the zone of discharge, assuming a leak at the edge of the disposal area. Multiplying predicted concentrations by quotients, obtained dividing likely leakage rates by the assumed rate, suggests carcinogenic leachate constituents would not occur in prohibited concentrations at the edge of the zone of discharge. But extrapolating in this fashion also suggests that violations may occur outside the zone of discharge, absent attenuation in the vadose zone, in the event of a leak at the edge of the Class I disposal area, for iron, manganese and methyl ethyl ketone. Groundwater Monitoring The City proposes to place monitoring wells at intervals of 250 to 500 feet around the Class I and Class III disposal sites. Some 25 shallow monitoring wells would be located 50 to 100 feet from the deposition areas, within the zone of discharge. In addition, seven clusters, each consisting of three wells screened at different depths, would punctuate the boundary of the zone of discharge. A cluster of wells upgradient would make it possible to monitor background conditions. With two-inch diameters and ten-foot screens, each well would receive a flow of less than a gallon a day. The contaminant plume from the Class III landfill would be large enough to be detected readily in samples drawn from a number of wells. But there was testimony that the plume, even from a 10-foot wide leak at the edge of the Class I disposal area, could pass between two wells 500 feet apart, undetected. Rather than a single large leak, moreover, the experts predict hundreds of small leaks in the Class I disposal area liner. The assumption is that flaws in the geomembrane would have an area of only one tenth of a square centimeter, on average. Any one of the plumes emanating from such a leak could easily pass undetected through a 500-foot gap between monitoring wells. The monitoring plan apparently relies on the great number of leaks expected. But even if samples from a monitoring well revealed a leak, the magnitude of hundreds of other leaks would not be disclosed. Well Contrived After the City filed its application for a permit to construct a landfill, but before DER had issued its notice of intent to grant the application, four wells were put in on the McCormick property, within three feet of the southern boundary of the City's property, and within 205 feet of the proposed Class III disposal area. The wells are more than 500 feet from the lined, Class I disposal area. Spaced at 1,000-foot intervals, within a 125- foot-wide utility easement in favor of the City of Jacksonville Beach, three of the wells are 25 feet deep and one is 28 feet deep. McCormicks' Exhibit No. 7. Each consists of a length of PVC pipe, 1 1/4" in diameter, leading to a red pitcher pump mounted on a wooden platform supported by four fence posts. City's Exhibit No. 194. Pumps of this kind must "periodically be pumped and primed or they have to periodically be taken apart and have the internal seals and leather valves replaced." T.2005. On April 7, 1988, the St. Johns River Water Management District issued a warning notice to "Haden McCormick" alleging that the wells had not been grouted, had been dug without necessary permits, and had not been the subject of required well completion reports. The next day, the St. Johns County Environmental Protection Board, apparently in response to applications inspired by the warning notice, issued a permit for each well designating the "usage" of each as irrigation. McCormicks' Exhibit No. 7. Well completion reports dated April 14, 1988, reported that the wells had been grouted. McCormicks' Exhibit No. 3. Asked the purpose of the wells in a deposition on April 25, 1988, J. T. McCormick said, "We need to monitor what [the landfill is] doing . . . [W]e need to . . . prepare ourselves for having people live in this area, to occupy it, to monitor it." T. 2227-8 A week earlier J. C. Williamson, Jr. had requested on behalf of B.B. McCormick and Sons, Inc. that the St. Johns County Environmental Protection Board amend the permits to show well usage as "Private Potable" instead of "Irrigation". This request was granted on April 27, 1988. McCormicks' Exhibit No. 2. On May 2, 1988, St. Johns River Water Management District's chief hydrologist wrote a lawyer for the McCormicks that "the completion reports submitted by a licensed driller, and the St. Johns County permits fulfill the requirements of the District." McCormicks' Exhibit No. 1. Analysis of samples of water taken from the wells on February 27 and 28, 1989, revealed total coliform levels acceptable for private wells. John Haydon McCormick explained the decision to put the wells in: [D]uring that week the City had filed their application with the DER which, in a sense, fixed their design . . . and when we became aware that this Class III landfill was as close as it is to our border, we became concerned about the future use of potable drinking water, and after consulting with counsel we were informed that we could legally install wells along that border. T. 2242. No owner of the property where the wells are located lives on the property nor, as far as the record shows, has an owner or anybody who does live on the property ever drunk water from the wells. About a half mile from the City's property are two other wells near a house on the McCormick property. When an owner's son drank water from one or more of the wells, as recently as the fall of 1988, he had to take water to the site with him in order to do it. The hand pumps require priming and nobody has bothered to store water near them for that purpose. On February 26, 1989, when the City's expert arrived for "splitting samples to submit to different laboratories," (T.1007) The "pumps were in a 20-gallon washtub in the back of . . . one of Mr. McCormick's employee's trucks. They were all removed from the well heads . . . [apparently] being soaked to generally recondition the seals in the pumps and to sanitize the pumps." T.2008 Two "of the old leather seals from the pumps [were] on the ground." T.2009. Within the shallow aquifer, groundwater flows from the wells northerly underneath the proposed Class III disposal area in the direction of Durbin Swamp. Use of the four existing wells "would in no way modify the groundwater flow system." T. 2045. But a well or wells could be so constructed on the McCormick property that continuously pumping from them would reverse some of the groundwater flow under the proposed Class III disposal area, to the extent that water flowing from beneath the Class III disposal area could be drawn from one of the existing wells along the McCormick boundary. T. 2075-80. Nor would consumptive use permits be necessary to dig wells which could cause such a change in groundwater flows. T. 2075. When the City discovered the wells abutting the southern boundary of its property, it did not direct its engineers to alter the design of the landfill to preclude solid waste disposal within 500 feet of the wells. The total project cost, excluding legal fees, is estimated in the neighborhood of $46,000,000. Redrawing the plans now to reduce the size of the Class III disposal area, without altering the size of the Class I disposal area, would take two to three months, and cost approximately $100,000. This approach would require reducing the capacity of the Class III area from 4.1 million cubic yards to 2.5 million cubic yards and, unless construction debris, which can be disposed of without a DER permit, were diverted elsewhere, its useful life from about ten years to about six years. Tipping fees would have to be higher "to recover the capital fixed costs over fewer tons." (T. 2208) Increased design costs alone would require recouping an additional 4 cents per cubic yard (more considering the time value of money) from tipping fees for Class III debris. Operations would be less efficient and presumably more expensive. T. 2207. Alternatively, the entire facility could be redesigned to achieve the same capacity and useful life as now contemplated. Such a redesign would require four to six months' work and cost approximately $250,000. Recovering this cost through increased tipping fees for Class III wastes would add slightly more than 6 cents a cubic yard (again ignoring the time value of money.) Alternative sites for disposal of Class III waste are available to the City. Indeed the site for which the City now seeks a permit was not even among the ten sites originally considered for the project. T. 2224-5. Decreased transportation costs to another site closer to the source of such waste might more than offset increased tipping fees. But separate facilities could create other problems. Ms. Nogas explained: From an operations standpoint . . .If I run out of Class III area and . . . site a separate Class III area somewhere else, if I had a truck coming to that facility and he really should have been in a Class I area, and I say "No, go out the gate and go five miles down the road . . .[to the] Class I facility," . . . I have a much better chance of . . . him never showing up at my Class I facility. T 2208-9. On the other hand, when asked about placing a Class III facility elsewhere in Duval County, Ms. Nogas, reiterating an earlier statement, testified, "[I]f that were what we had to go to, I would have no operational problems with it." T. 221. Mr. Wells' testimony that there "are 16,000 acres of less environmentally flawed acres seven to 12 miles from the generating centroid accessible from four-lane roads and not near residential or commercial properties," (T. 1248) and that the proposed site "is the furtherest site from the generating centroid, 21 and three-quarters miles to the dump site, and will cost taxpayers an extra $3 million to $5 million a year in longer haul time" (T. 1247) was received on the issue of the decisionmakers' credibility only.
Recommendation It is, accordingly, RECOMMENDED: That DER deny the City's request for variance. That DER deny the City's application for a permit to construct a landfill. That DER deny the City's application for a dredge and fill permit. That DER grant the City's application for a permit for management and storage of surface waters, on conditions proposed in the intent to issue, unless modified by agreement of all parties. DONE AND ENTERED this 16th day of October, 1989, in Tallahassee, Leon County, Florida. Robert T. Benton, II Hearing Officer Division of Administrative Hearings The DeSoto Building 1230 Apalachee Parkway Tallahassee, Florida 32399-1550 (904) 488-9675 Filed with the Clerk of the division of Administrative Hearings this 16th day of October, 1989. APPENDIX A Petitioner St. Johns County's proposed findings of fact Nos. 1-4, 6, 10-12, 14, 16, 18, 21,23, 24-28, 33, 35, 37, 38, 41-45, 47-48, the first sentence of No. 51, Nos. 52-56, 57 except for the first sentence, which is rejected, 58, 59, 62, 64, 66, 68-74, 95-103, 106-109, 111- 116, 118, 131, 132, 133 except for subpart 7, 134, 136 and 137 have been adopted, in substance, insofar as material. With respect to petitioner St. Johns County's proposed finding of fact No. 5, and the second sentence of petitioner St. Johns County's proposed finding of fact No. 51, the design rate is not the same as the current rate of deposition. Petitioner St. Johns County's proposed findings of fact Nos. 7, 8, 9, 13, 15, 17, 22, 75, 110 and 138 relate to subordinate matters. Petitioner St. Johns County's proposed finding of fact No. 19 accurately recites the testimony. Petitioner St. Johns County's proposed finding of fact No. 20 is immaterial. With respect to petitioner St. Johns County's proposed finding of fact No. 29, the City's evidence that leakage of this kind was insignificant went unrebutted. Petitioner St. Johns County's proposed findings of fact Nos. 32 and 120-123 are immaterial to the present application. With respect to petitioner St. Johns County's proposed finding of fact No. 30, the City's estimates were unreasonably low. With respect to petitioner St. Johns County's proposed finding of fact No. 31, the evidence showed that nine gallons a day was at the upper limit, not that it would actually occur. With respect to petitioner St. Johns County's proposed finding of fact No. 34, at least 13 substances occur in concentrations that exceed health-based standards. Petitioner St. Johns County's proposed findings of fact Nos. 36 and 63, 117, 119 and 135 are proposed conclusions of law. With respect to petitioner St. Johns County's proposed finding of fact No. 39, the probability of a leak on the edge of the disposal area was not established. With respect to petitioner St. Johns County's proposed finding of fact No. 40, the evidence did not show that when "two or more toxic substances are combined" they necessarily have synergistic impacts. With respect to petitioner St. Johns County's proposed finding of fact No. 46, the City's assumption of no attenuation was an appropriately conservative approach that is not inconsistent with the City's unrefuted testimony that attenuation would occur. With respect to petitioner St. Johns County's proposed finding of fact No. 49, the evidence did not prove that the City would allow four feet of leachate to stand on the liner. Petitioner St. Johns County's proposed findings of fact Nos. 50 and 60 immaterial to the present application. With respect to petitioner St. Johns County's proposed finding of fact No. 61, the evidence did not establish the contentions following the clause ending "and into Durbin Creek,". With respect to petitioner St. Johns County's proposed findings of fact Nos. 65 and 67, the McCormick wells have served ornamental and talismanic purposes, but they were not shown to be potable water supply wells, within the meaning of the rule. At the time of hearing the pumps did not function and were not mounted on the wells. Petitioner St. Johns County's proposed finding of fact No. 76 has been adopted, in substance, insofar as material, except that there was at least one effort to collect toxic wastes in Jacksonville. With respect to petitioner St. Johns County's proposed findings of fact Nos. 77 through 94, proposed permit conditions are not proposed findings of fact. With respect to petitioner St. Johns County's proposed finding of fact No. 124, the evidence was clear that more wetlands were to be destroyed than were to be created. Petitioner St. Johns County's proposed finding of fact No. 125 is rejected as against the weight of the evidence. With respect to petitioner St. Johns County's proposed findings of fact Nos. 126, 127 and 128, mitigation , particularly as regards the wood stork, if the landfill is built. Petitioner St. Johns County's proposed finding of fact No. 129, Durbin Creek enters Julington Creek, shortly before the latter reaches the river. Findings of fact proposed by petitioners J.T. McCormick and the Estate of Benjamin R. McCormick (McCormicks) Nos. 1-4, 6-10, 13, 15-17, 20, 21 and 23 have been adopted, in substance, insofar as material. With respect to McCormicks' proposed finding of fact No. 5, a preponderance of the credible evidence did not establish that the wells would be used to supply potable water in the future, even if the pumps are repaired to make it possible. Nor did the evidence establish any such authentic, "non-forensic," use in the past. With respect to McCormicks' proposed finding of fact No. 11, evidence was adduced that other sites had been considered by engineers the City engaged. T. 2224-5. With respect to McCormicks' proposed finding of fact No. 12, testimony put the delay at two to three months. T. 2139. The City could have avoided this delay. McCormicks' proposed finding of fact No. 14 has been adopted, in substance, insofar as material, except that the proportion of the Class III waste stream construction and demolition debris comprises is not stated at T. 2149. With respect to McCormicks' proposed findings of fact Nos. 18 and 19, the four and six cents per ton computations ignore the time value of money, among other things. McCormicks' proposed finding of fact No. 22 is immaterial. McCormicks' proposed finding of fact No. 24 is properly a proposed conclusion of law. Findings of fact proposed by Florida Wildlife Federation, Inc., St. Johns County Audubon Society, Sierra Club, Inc., Coastal Environmental Society and River Systems Preservation, Inc. came in two unnumbered installments. Findings of fact have addressed the substance of each. Without numbering, it is difficult to treat the material. Petitioner STOP's proposed findings of fact Nos. 5-7, 9-10, 12-18, 20, 22- 24, 26-27, 29, 32-47, 49, 50, 52, 55-57, 59-60, 62, 63, 66, 67, 69, 70, 72 and 73 have been adopted, in substance, insofar as material. Petitioner STOP's proposed findings of fact Nos. 1-4, 30, 31, 65, 71, 75 and 76 are properly proposed conclusions of law in part and relate otherwise to DER's preliminary analysis, which is technically immaterial. With respect to petitioner STOP's proposed findings of fact Nos. 8 and 58, Mr. Kappes said he had seen alligator on site but, when asked for specifics, testified to tracks they had left in the southeast corner of the site. Equally ambiguously, the City stated in its draft application that alligator had been "noted" on the property. The evidence did not show that ospreys are protected or listed in Duval County. Petitioner STOP's proposed findings of fact Nos. 11 and 74 relate to subordinate matters. With respect to petitioner STOP's proposed finding of fact No. 19, the inference that all commensals is present is problematic here, since the gopher tortoises were relocated by man from a site many miles away. With respect to petitioner STOP's proposed finding of fact No. 21, 80 to 82 of 105.7 acres of gopher tortoise habitat would be destroyed. Petitioner STOP's proposed finding of fact No. 25 is immaterial to this application. With respect to petitioner STOP's proposed finding of fact No. 28, Mr. Wiley so testified. With respect to petitioner STOP's proposed findings of fact Nos. 48, 51 and 64, although the conservation easement on uplands would not result in additional habitat, it would preclude further diminution. With respect to petitioner STOP's proposed findings of fact Nos. 53 and 54, no eagles are currently nesting on site, and Eagle Nest Island, where eagles nested until 1983, is off site. With respect to petitioner STOP's proposed finding of fact No. 61, the evidence did not establish that Mr. Kappes saw the red-cockaded woodpecker on site, even though he found six active nests within three miles of the site. With respect to petitioner STOP's proposed finding of fact No. 68, Dr. White so testified. DER's proposed findings of fact Nos. 1-9, 11-15, 17, 24, 26, 33, 37, 39, 41-45, the first three sentences of No. 50, Nos. 52-56, 62-64, 66, 67, except as regards inherent legislative facts, 70-87, 89-92 and 95 have been adopted, in substance, insofar as material. With respect to DER's proposed finding of fact No. 10, 0.9 acres of wetlands contiguous to Durbin Swamp and within the jurisdiction of the St. Johns River Water Management District would be used for a storm water retention basin. DER's proposed findings of fact Nos. 18 and 20 have been adopted, in substance, except that these steps do not ensure or guarantee a quick return of water quality functions. DER's proposed findings of fact Nos. 21, 32, 35, the last sentence of No. 50, Nos. 51, 88 have been rejected as against the weight of evidence. With respect to DER's proposed findings of fact Nos. 22 and 28, mitigation areas with deep ponds in the middle will permit fish to avoid the conditions under which wood storks feed. With respect to DER's proposed finding of fact No. 23, the steep sided ponds, sparser canopies and lesser extent of created isolated wetlands offset their "higher quality." With respect to DER's proposed finding of fact No. 25, the mitigation proposed does not amount to a one to one ratio. While significant, the easements preserve the status quo and do not compensate for lost wetland functions. With respect to DER's proposed finding of fact No. 27, the evidence suggested no reason why bears would not forage in isolated, as well as contiguous wetlands. With respect to DER's proposed finding of fact No. 29, to the extent possible, existing trees would be transplanted; if they all survived, the number of perches would be undiminished, except for branches broken in the process. With respect to DER's proposed finding of fact No. 30, sightings nearby and habitat on site amount to evidence of use of the site. As regards the indigo snake, testimony that these animals were introduced to the site was uncontroverted. With respect to DER's proposed finding of fact No. 31, alligator tracks were found in the southeastern part of the site. With respect to DER's proposed finding of fact No. 34, no southeastern kestrel nests were found on site. With respect to DER's proposed finding of fact No. 36, it is not in the public interest to issue a permit for a lined landfill that would cause pollution in violation of DER's water quality standards. If a landfill were properly permitted, it would be in the public interest to have access. With respect to DER's proposed finding of fact No. 38, the first sentence (which seems to contradict the fourth) has been adopted, in substance, insofar as material. With respect to DER's proposed finding of fact No. 40, there was no evidence of cumulative impacts to Durbin Swamp, as opposed to Durbin and Julington Creeks. With respect to DER's proposed findings of fact Nos. 46-48, the clayey sand, placed in two six-inch lifts, would have much greater permeability as a unit than samples of the same material screened for certain imperfections and tested in the laboratory. In the field, it would not be possible to remove all clods and other materials that make for greater vertical hydraulic conductivity of the unit. Subgrade mixing would occur, in putting down the first of the two lifts. A 12-inch layer would be many more times transmissive than a liner of the same material put down in six six-inch lifts to attain the three feet DER requires, when no synthetic liner is used. Mr. Fluet did not testify that a 12-inch layer would achieve a permeability of 1 x 10-7 centimeters per second. He testified that nobody who had studied 12-inch layers had reported permeability of less than 1 x 10-5 centimeters per second for a clayey layer of that thickness. With respect to DER's proposed finding of fact No. 49, the geomembrane is subject to the effects of pressure and temperature variation would contribute to wrinkling. With respect to DER's proposed finding of fact No. 57, leachate leakage would diminish after closure, but would not stop altogether. With respect to DER's proposed findings of fact Nos. 59 and 60, the working hypothesis is that even a single molecule of certain leachate constituents may initiate cancer, although concentrations below the levels identified are said to pose no more than an acceptable risk of doing so. DER's proposed finding of fact No. 61 describes the methodology correctly, but the particular results have not been accepted. With respect to DER's proposed finding of fact No. 65, predicted concentrations depend on the leakage rate assumed. With respect to DER's proposed finding of fact No. 68, data showing the composition of discharges to ground water from other Class III landfills were not presented. Supposed "legislative facts" do not constitute evidence. With respect to DER's proposed finding of fact No. 69, the evidence did not show what concentrations of biocides or other chemical constituents were likely to be. With respect to DER's proposed finding of fact No. 93, the phrase "monitoring well" was not used. With respect to DER's proposed finding of fact No. 94, wells Nos. 21 and 22 were between 25 and 35 feet deep. Haydon McCormick testified that a shallow well near the house was for potable water supply. DER's proposed finding of fact No. 96, has been adopted, in substance, except that additional time might not be required for permitting. With respect to DER's proposed findings of fact Nos. 97 and 99, balancing of social and economic interests is appropriate only if hardship is proven, and immaterial otherwise. The City's proposed findings of fact Nos. 1-9, 16-18, 20-25, 30, 33, 35-38, 42, 44, 46, 49, 50, the first two sentences of No. 55, Nos. 58-62, 65, 73, 74, except for the last sentence, Nos. 75, 77-83, 88-92, 94-100, 104, 107, 108 and 110 have been adopted, in substance, insofar as material. With respect to the City's proposed finding of fact No. 10, despite timbering of the uplands the site was characterized as "relatively unaltered." With respect to the City's proposed finding of fact No. 11, no decline in water levels was shown to be irreversible. With respect to the City's proposed finding of fact No. 12, the study was of "trivial value." With respect to the City's proposed finding of fact No. 13, bald eagles and wood storks do make use of the site and indigo snake(s) were set loose there. With respect to the City's proposed finding of fact No. 14, a witness testified to his "confidence" (T.2918) that the kestrel he spotted was a Southeastern kestrel. Signs of alligator were found near the southeast corner of the property. With respect to the City's proposed finding of fact No. 15, hunting was mentioned. The City's proposed findings of fact Nos. 19, 54, 56 and 84 pertain to subordinate matters. With respect to the City's proposed finding of fact No. 26, the witness so testified. With respect to the City's proposed finding of fact No. 27, it was not proven that noise would be "minimized." With respect to the City's proposed finding of fact No. 28, bears could move through the culvert, but elsewhere the access road (particularly during the day), fences and human activity on site would indeed "impede black bear movement in the area." The City's proposed findings of fact Nos. 29, 48, the last sentence of 55, Nos. 57, 71, 72, 85, 87 and the last sentence of 101 have been rejected as being against the weight of the evidence or as unsupported by the preponderance of evidence. With respect to the City's proposed finding of fact No. 31, mobility will not assure successful relocation if existing populations are fully utilizing habitat in the vicinity. The City's proposed findings of fact Nos. 32, 86 and 93 are properly proposed conclusions of law. With respect to the City's proposed finding of fact No. 34, groundwater was shown unlikely to reach solid waste on site. With respect to the City's proposed finding of fact No. 40, the maximum head would not be less than one inch. With respect to the City's proposed finding of fact No. 41, such sand might not be available on site. With respect to the City's proposed finding of fact No. 43, some leachate would leak through the liner. With respect to the City's proposed finding of fact No. 45, some rainwater would infiltrate. With respect to the City's proposed finding of fact No. 47, the evidence did not show that the clayey sand layer would attain so low a vertical hydraulic conductivity. If these liners have performed well, it has not been without leakage, both through flaws and by permeation. With respect to the City's proposed finding of fact No. 51, the subgrade would be inspected, in an effort to assure complete removal of sharp objects. With respect to the City's proposed findings of fact Nos. 52 and 53, permeability is specific to the permeant. The values quoted are for water. High density polyethylene is highly permeable to aromatic hydrocarbons. That liners leak is not speculation. With respect to the City's proposed finding of fact No. 63, the design engineer envisioned circumstances that would require backing leachate up in the landfill. With respect to the City's proposed finding of fact No. 64, violations were proven, in the absence of sufficient attenuation in the vadose zone, and attenuation there was not quantified. With respect to the City's proposed findings of fact Nos. 66 and 67, these evaluations assumed unrealistically low leachate leakage rates. With respect to the City's proposed finding of fact No. 68, this elaborate house of cards bears little relationship to the language of the free from rule. But this approach, too, shows violations, if realistic leakage rates are used. With respect to the City's proposed finding of fact No. 69, credible and credited evidence of dramatically higher leachate leakage rates than they assumed contradicted their conclusions. With respect to the City's proposed finding of fact No. 70, the witness so testified. With respect to the City's proposed finding of fact No. 76, the precise constituents of the Class III leachate were not proven. With respect to the City's proposed finding of fact No. 102, the witness so testified. With respect to the City's proposed finding of fact No. 103, the well that Haydon McCormick jetted in was 25 to 35 feet deep. With respect to the City's proposed findings of fact Nos. 105 and 106, wells could be placed so that enough water drawn from them would reverse the gradient and cause pollutants to move toward the McCormick property. With respect to the City's proposed finding of fact No. 109, the evidence about the effect on operations was ambiguous. With respect to the City's proposed finding of fact No. 111, it is unlikely that the McCormicks would take steps to reverse the flow of groundwater. APPENDIX B Three methods of calculating per defect leachate leakage rates (in cubic meters per second) were proven at hearing, each expressed as an equation or formula requiring values for three variables, for their solution, viz.: h = height of leachate head over defect (in meters) a = area of defect (in square meters) Ks = permeability (vertical hydraulic conductivity) of clayey sand layer beneath defect (in meters per second) The method advocated by the City, published by the EPA, and shown (by the author) to reflect ideal contact between liner components, which does not obtain in practice, is: Q = (0.7) x (h) x (a0.1 x Ks0.88). The method advocated by the County, endorsed by the author of the formula EPA published, and shown to reflect good contact between liner components, shown likely to occur in places, is: Q = (0.21) x (h0.9) x (a0.1 x Ks 0.74) The method advocated by the County, endorsed by the author of the formula EPA published, and shown to reflect poor contact between liner components, shown likely to occur in places, is: Q = (1.15) x (h0.9) x (a0.1 x Ks 0.74) In each case, Q represents the flow of leachate through each defect. COPIES FURNISHED: Carlos Alvarez and Carolyn S. Raepple Hopping, Boyd, Green and Sams Post Office Box 6525 Tallahassee, Florida 32314-6526 Harrison D. Upchurch and Frank D. Upchurch, III Upchurch, Bailey, and Upchurch, P.A. Post Office Box 170 St. Augustine, Florida 32085-0170 Joseph M. Glickstein, Jr. Glickstein and Glickstein 444 Third Street Neptune Beach, Florida 32233-5111 David S. Dee and Allan Wagner Carlton, Fields, Ward, Emmanuel Smith & Cutler, P.A. Post Office Drawer 190 Tallahassee, Florida 32302 C. Rufus Pennington, III Margol and Pennington, P.A. Suite 1702, American Heritage Tower 76 South Laura Street Jacksonville, Florida 32202 Debra Swim 1323 Diamond Street Tallahassee, Florida 32301 Sidney F. Ansbacher Turner, Ford and Buckingham, P.A. 1904 Gulf Life Tower Jacksonville, Florida 32207 Dan Brooks Hendrickson and 104 Sixth Avenue 4620 Arapahoe Avenue Pass-A-Grille, Florida 32706 Jacksonville, FL 32208 Frank X. Friedman, Jr. T. R. Hainline, Jr. G. Stephen Manning Marcia P. Parker Rogers, Towers, Bailey, Jones & Gay 1300 Gulf Life Drive Jacksonville, Florida 32207 William H. Congdon and Chris McGuire 2600 Blairstone Road Tallahassee, Florida 32399-2400 Kathryn L. Mennella Post Office Box 1429 Palatka, Florida 32078-1429 Larry Gilmore 9131 Fort Caroline Road Jacksonville, FL 32225 Larry A. Wells 237 Pablo Road Ponte Vedra Beach, FL 32082 Dale H. Twachtmann, Secretary Department of Environmental Regulation 2600 Blair Stone Road Tallahassee, FL 32399-2400 =================================================================
Findings Of Fact Respondent, Textron Petroleum Products Company, Inc., has applied for a construction permit to construct a sanitary landfill in Sections 3 and 10, Township 1 North, Range 2 East, Leon County, Florida. The proposed site consists of ninety (90) acres and is approximately 2,000 feet from U.S Highway 90 at Its closest point to that highway. The application is in proper form and contains all information required by the Department of Environmental Regulation. towns and areas to be served by the application are the City," of Tallahassee and Leon County. The facility is designed to serve a population of 135,000 people. Although evidence was presented for the purpose of showing that the City of Tallahassee and Leon County, as governmental entities, do not intend to use the proposed sanitary landfill as an "official" landfill site for those governmental bodies, this evidence did not establish that the area to be served and the population to be served by the proposed sanitary landfill is other than that stated above. The applicant, Textron Petroleum Products Company, Inc. does not have a franchise from any county, municipality or other governmental agency with regard to solid waste resource recovery and management responsibilities. The applicant, Textron Petroleum Products Company, Inc., had not, at the time of hearing, posted a performance bond or other approved security with the agency within whose jurisdiction the proposed site is located. The "owner" as that term is used in Section 17-4.21(1)(d), F.A.C., is the applicant, Textron Petroleum Products Company, Inc. The unrebutted evidence presented,at hearing established that the applicant has a net worth of $1 million and is financially responsible. The evidence presented did not establish any violation of the State Resource Recovery And Management Program set out in Part II, Chatper 17-7, F.A.C. There is a public supply well located in the Homestead Ridge area. This system serves 38 or more customers at an averave rate of about 200,000 gallons per month. The well is located more than 2,700 feet from the site boundary of the proposed sanitary landfill. As found by the Northwest Florida Water Management District, even if the consumption of that well system were increased to 2.16 million gallons of water per month, the drawdown at a radius of 2,000 feet would be 0.13 feet. Therefore, it was concluded that the cone of influence of the public water supply does not extend under the proposed sanitary landfill site. As a condition for issuance of a construction permit the Department of Environmental Regulation proposes the requirement of a monitoring system of wells which would include a deep well located between the proposed site and the Homestead Ridge public supply, the purpose of which would be to detect the potential intrusion of leachate or other contaminants into the public water supply from the sanitary landfill. It is improbable that the proposed sanitary landfill will produce any significant quantity of leachate. However, the application proposes that if monitoring indicates that lechate control is needed, a well point system will be installed in the completed cells and underground pipe drains installed in the new cells. It further provides that, dependent upon the quantities involved, the leachate.will be transported to the City of Tallahassee Sewage Treatment Facilities for disposal or it will be treated on-site by transporting the leachate to the settling pond which will at that time be equipped with suitable aeration and chlorination equipment for treatment of the leachate. The proposed design of the sanitary landfill provides that all final discharge from the sedimentatlon pond will conform to the water quality standards set out in Chapter 17-3, F.A.C, even though this may require the constrjction of treatment equipment by the applicant. The application, at pages 12 and 14,.provides for the equipment to be used on-site in the operation of the proposed sanitary landfill as well as for the method of providing adequate site supervision. No evidence was presented showing these provisions to be other than adequate. The evidence presented did not establish that the utilization of U.S. Highway 90 by vehicles transporting waste to the proposed sanitary landfill would create any unusual 0rincreased traffic and safety hazard. The application, at page 3, proposed the installation of electronic signalization equipment to alleviate any hazard which might be created by traffic using the proposed site. No evidence was presented showing this proposal to be inadequate. According to a letter to Mr. James Barrineau, Leon County Department of Pollution Control, from Mr. Mark Stamps, Assistant Zoning Director, Tallahassee Leon County Planning Department, the proposed site is currently zoned Agricultural 2. The letter further states that an Agricultural 2 zoning allows a sanitary landfill as a permitted use. A small portion of the proposed sanitary landfill site is open to public view from,U.S. Highway 90 which is a major thoroughfare. It was estimated by a witness that the distance to the proposed site from that section of U.s. Highway 90 from which the site was open to public view was one (1) mile. An examination of the plot plan of.the proposed site contained in the application shows that at the closest point, the site boundary is approximately 2,000 feet from U.5 Highway 90. The site is screened from public view from most places on Highway 90 by the existing topography and ground cover.
The Issue Whether Beker Phosphate Corporation should be granted a hermit to construct an industrial waste water facility pursuant to chapter 403, Florida Statutes. By application, dated April 8, 1975, Beker Phosphate Corporation (hereinafter Beker) , sought a permit to construct an industrial waste water facility in Manatee County, Florida, from the Department of Pollution Control (now and hereinafter DER) . The application was received on April 11 and, after advising Beker that the application was incomplete a meeting was held on May 9th between DER and Beker representatives with the result that Beker filed a new application dated June 11, that was received by the DER in July. Further meetings were held in the fall of 1975 and additional in formation was received as to the application. On December 16, 1975, DER secretary. Jay W. Landers, Jr., issued a Notice Of Intent To Grant A Permit With Conditions. The conditions were unspecified in the letter of intent (Exhibit 1.) Subsequently, on December 23 and December 24, 1975, Sarasota County (hereinafter Sarasota) and the Town of Longboat Key (hereinafter Longboat Key), respectively, filed petitions with the DER alleging that their substantial interests would be adversely affected by approval of the permit application and setting forth in their petitions certain disputed questions of fact for determination. After a prehearing conference, Amended Petitions were filed by those parties to clarify and expand on such questions of fact and to resolve procedural matters. Additionally, during this period, George Browning, III, of Sarasota, Florida was granted status as an intervenor.
Findings Of Fact Beker proposes to construct a phosphate rock mine and beneficiation plant on a tract of approximately 11,000 acres in a predominately agricultural and ranching area of Manatee County about 10 miles from Myakka City, Florida. The mining will be performed by two dredges. One will mine overburden and return it to the mined-out area and the other will mine phosphate rock matrix which will be pumped to the beneficiation plant. The plant will consist essentially of two circuits. The first is a washer where the matrix pumped from the dredging operation is partially cleaned of clay and fine sand, and the coarser phosphate particles "pebbles" are separated as a product. The "fines" from the washing operation consist of small phosphate rock particles, sand, and clay. This mixture will be treated in the second section of the plant by "flotation" methods to recover the small phosphate rock particles as a product. During initial operation, the sand and clay will be stored in a temporary waste material storage area, but as the mining proceeds and the dredge pits open up, the sand and clay material will be pumped back to the dredge pits so that sand, and overburden will be mixed and redeposited to reclaim the land. Approximately 8 million gallons of fresh water per day will be drawn from the Floridian aquifer to be used in the flotation circuits. From the plant the water flows in two types of streams--one containing sand suspended in water and one containing clay suspended in water. Both streams flow into a settling pond surrounded by an earthen dam where sand and clay solids settle to the bottom. The clarified water is then decanted through six spillway structures into a hydraulic recirculation ditch outside the dam and flows back to the plant for re-use. The ponds and canals that make up the hydraulic circuit are planned to have sufficient capacity to contain rainwater falling on the site and pond system during the wet season when there are heavy rainfalls (approximately from May to September). Excess water will be decanted from the hydraulic recirculation ditch through a structure into a pipe and then discharged into Wingate Creek. The settling pond will occupy approximately 225 acres and its capacity will be about 8,458 acre- feet. The pond itself can be used to act as a reservoir and water can be built up in the pond during periods of high rainfall. It will not be necessary to release the water at any particular time. It can be released at will when the effluent contains a minimum of pollutant materials (Exhibit 1). Matrix is an unconsolidated mixture of phosphate pebbles and boulders of partly phosphatized limestone, quartz and clay. The washing operation removes unwanted oversized material and fine clays. The purpose of the flotation plant is to recover fine phosphate rock that might otherwise be lost. In the flotation process, flotation reagents, including sulfuric acid, number 2 fuel oil, tall oil, sodium hydroxide, and amines are used for treatment. The wastes are then moved to the settling pond where over a period of time the "slimes", (sands and clays) will settle to the bottom forming an impervious layer which will seal the pond. The settling process removes more than 90 percent of the contaminants from the influent. The coarser clay particles settle first and many of the fine particles settle in a process called "flocculation" by which electrical forces bring the particles together. However, some of the particles will not flocculate and remain suspended in the water. These extremely small particles constitute the total suspended solids that remain in the effluent when it is discharged from the settling area. They probably will not settle out entirely during their course from Wingate Creek into the Myaaka River and eventually to the Gulf of Mexico. However, even if it were assumed that such materials would settle somewhere between the point of discharge and Charlotte Harbor, over the entire 20 year proposed life of the mine they would form a deposit much less than 1/10th of an inch. Although it is technically possible to treat water to the degree that it would result in distilled water, realistic concepts of treatment establish that an additional settling or "polishing" pond for the proposed facility might not improve the quality of the wastewater finally discharged in state waters to any appreciable degree. Alternative proposals for the reduction of pollutants by additional processing, such as the intentional growth of water hyacinths in settling areas or use of chemical coagulants would result in creating other waste materials and thus be counterproductive (Testimony of Bromwell; Exhibit 1). The applicant's discharge of wastewater to Wingate Creek will average approximately 3.19 million gallons per day. However, since discharge will be effected primarily during periods of excessive rainfall, actual discharges can reach a maximum of about ten million gallons per day during this period. The effluent contained in such discharge will meet the test of at least 90 percent removal of organic and inorganic wastes specified by Rule 17-3.04(1), Florida Administrative Code, when measured by the influent into the settling pond and the effluent leaving that area. This treatment, however, will not produce an effluent equivalent to that produced by the "highest quality municipal waste treatment." The highest degree of treatment that has been reached by municipalities is "advanced waste treatment" as defined in Rule 17-3.04(2)(b), Florida Administrative Code. The water quality characteristics of the effluent will meet the standards of Rule 17-3.05 as to concentrations of those pollutants reasonably anticipated to be fond in the wastewater based on samples taken where the waters are discharged into Wingate Creek (Testimony of Gilgallon, Davis, Edwards, Heinzman, Bromwell, Bartow, Wellford, Exhibit 1). In preparing the application, no consideration was given to the need of meeting treatment standards for highest quality municipal waste treatment or advanced waste treatment. Neither did the recommending official of the DER, Mr. Edwards, then Regional Administrator for the Southwest Region, consider this standard because he had been advised by the DER legal staff that Rule 17-3.04(2) did not apply to Wingate Creek since it was not a tributary to one of the bodies of water listed in subparagraph (c) of the rule 17-3.04(2). This determination was based upon Resolution No. 74-83, September 17, 1974, of the Florida Pollution Control Board that was issued after legal challenges had been made to an interpretation by the Department of Pollution Control legal staff that Rule 17-3.04(2) required advanced wastewater treatment for industrial waste discharges. The Board, in its resolution, determined that since evidence had not been taken concerning treatment standards for industrial waste discharges at the time of adoption of the effluent standards for sanitary waste contained in Rule 17-3.04(2), the advanced wastewater treatment standards in the aforesaid rule would not be enforced against industrial dischargers pending full hearings on a new Rule to clearly express the Board's intent in this regard (Testimony of Gilgallon, Edwards; Exhibit 1). Special conditions that the Southwest Region, Department of Environmental Regulation, recommends should be attached to any issuance of a construction permit, other than standard conditions and those relating to other types of permits, are as follow: Approval by DER prior to the construction of any above grade phosphatic clay storage facility other than the initial settling pond. Removal efficiencies for oil and grease shall be a minimum of 90 percent and shall not exceed 14 milligrams per liter measured in the discharge effluent. Discharge effluent to Wingate Creek shall meet the water quality standards of Chapter 17-3.05(2) at the point of discharge prior to mixing with the receiving stream. Further treatment of the discharge will be required in the event compliance with proviso (c) above cannot be achieved or significant degradation of the receiving stream occurs as determined by the DER. In addition to required routine monitoring, a detailed analysis of the untreated and treated wastewater to be conducted once on representative samples during (1) month of July and (2) month of February. Such analyses shall, as a minimum, include all the parameters listed in 17-3:05(2). Applicants shall conduct an investigation into total retention possibilities of the effluent including, but not limited to, the following areas: recharge wells retention and storage of excess water during the "wet" season with subsequent reuse during the "dry" season for process and/or irrigation purposes. A report of these investigations shall be submitted prior to submission of operation permit application The location of monitoring wells shall be down gradient from the settling pond. Detailed proposal, subject to the DER approval, regarding exact location and number of wells to adequately ascertain the impact of seepage to be submitted no later than 90 days prior to commencement of operation. Bond to be posted for damages that may result from a clay settling area dam failure. Oral and written communications from the public were received at the hearing and included the following: Announcement by the County Attorney, Manatee County, that the county did not plan to appeal the DER Notice of Intent to Grant the permit (Statement of E.N. Fay, Jr.). The Division of Recreation and Parks, Department of Natural Resources, fears that the construction of the phosphate mine up-stream from the Myaaka diver State Park poses a serious potential threat to its aquatic habitat due to the possibility of a dam failure. It also fears that pollutants from the project will tend to settle as the river waters flow through the two lakes in the park. It therefore, opposes the construction until assurance can be given that proper safeguards have been taken to prevent such problems (Testimony of Alverez). The Longboat Key Garden Club believes that the project would involve too much water consumption and also that phosphate mining should be halted until further government studies are made to assure that the safety and health of the populace and the environment will not be endangered through polluted runoff and phosphate spills (Testimony of Monroe). The Save Our Bays Association in Manatee County has collected petitions from citizens in Manatee County requesting a referendum on a ballot this November for or against phosphate mining. The Association believes that such a vote should be taken before final decision is made on the subject. Its spokesman fears that if the quality and quantity of the drinking water is disrupted, it will interfere with continued tourist trade (Testimony of Howard Greer). The Palma Sola Parks Association opposes the Beker Application until there is greater assurance of environmentally safe mining (Testimony of Blankenship) A former physical and health education director is concerned about the fact that there has not been sufficient data collected on the effect of radioactive materials in runoff and waste. She believes there should be more research in these areas and asked that the public be protected from such hazards (Testimony of Mary Kay Greer). The Manasota-88 project for environmental qualities of 1968 and 1988 believes that issuance of the permit should be withheld until health implications can be determined concerning potential hazards to the Myakka and Manatee Rivers' watersheds (Exhibit 7). A former member of the Manatee County Planning Commission that approved the Beker application prior to action by the County Commission of Manatee County is in favor of the proposed project because Beker's plan to impound water will augment the water facilities of the county (Testimony of Reasoner). The City of Bradenton believes that since it is being required to meet advanced water treatment standards of discharge for sanitary sewage, Beker Phosphate Corporation should be required to meet similar standards (Testimony of Mayor A.K. Leach). A member of the Myakka City Civic Association who is an adjacent land owner to Beker Phosphate Corporation feels that the project is necessary in order to produce jobs for individuals in that area of the county (Testimony of Mizell). The U.S. Fish and Wildlife Service is concerned that proposed construction of two dams by the applicant will destroy approximately (4) acres of mangrove areas, three acres of pasture land and about 185 acres of bottom land or hardwood habitat. It recommends an alternative method of backup levies constructed around the primary settling bases on the applicant's land to contain any spills and prevent destruction of the streams and associated wetlands (Testimony of Johnston) The Conservation Council of Manatee County believes that Beker's unique mining and reclamation plan will help the farming industry and also create necessary water reserviors and recreation areas, and therefore endorses its proposal to mine in Manatee County (Testimony of Kent, Exhibit 14). Petitions were submitted at the hearing from approximately 3,000 individuals living in Manatee and Sarasota Counties opposing the issuance of the permit because they believe that phosphate mining is dangerous to the quality and supply of the water and endangers the health of the people (Composite Exhibit 9, Testimony of Humphrey).
The Issue Whether WACOC has given reasonable assurance that the landfill it proposes to build would comply with applicable requirements of Chapter 403, Florida Statutes (1987), and rules promulgated thereunder?
Findings Of Fact A mile east of the intersection of U.S. Highway 90 and State Road 393, south of Dorcas in eastern Okaloosa County, WACOC has assembled some 1,760 acres on U.S. Highway 90 --- only 160 acres shy of three square miles. WACOC proposes to use as much of the land as possible for the disposal of solid waste, and "would like to use the proposed landfill as a regional landfill." Prehearing Stipulation, p.8. (T.68) The company does not own all the land outright but, with the conveyance of a parcel on the morning the final hearing began (T.77), WACOC had obtained (an encumbered) fee interest in the 55 acres on which it proposes to put Phase I, "a hole-in-the-ground landfill which can come into contact with the groundwater table," (T.737) and the subject of the pending application. WACOC has a "whole lot of option money out there," (T.86) although none of WACOC's stockholders has previous experience in the landfill business. Private Enterprise Chris Cadenhead owns stock individually and "is 100 percent owner of SRD, Incorporated" (T.93), itself an owner of WACOC stock. Serving with Chris Cadenhead and Larry Anchors on WACOC's board of directors, at the time of the hearing, was James Ward, formerly a legislator and chairman of the House Natural Resources Committee. (T.48) Like Mr. Anchors, Mr. Ward originally owned 24% of WACOC's stock. The only shareholder who testified at the hearing was Arthur Frederick Schneider. Before he succeeded Mr. Cadenhead as president of WACOC, Mr. Schneider had had a distinguished career as a naval officer, and later tried his hand at farming, but this venture ended in bankruptcy. "SRD has been funding this thing." (T.86) Where SRD, Inc. obtained more than three-quarters of a million dollars is not clear from the record. As far as the evidence showed, Chris Cadenhead's father, Rhett, had no interest in WACOC, although he did appear on behalf of the company at a county commission meeting in June of 1987. Larry Anchors, a WACOC shareholder and formerly an Okaloosa County Commissioner, contributed $35,000 a few days after the Okaloosa County Commission awarded the waste disposal contract. (T.87) Nothing has been paid the company under the agreement WACOC entered into with Okaloosa County on June 18, 1987, Citizens' Exhibit No. 1, which was reduced to writing on or before July 10, 1987. WACOC's Exhibit No. 1, App. 1. Under the contract, WACOC undertakes to move solid waste from transfer points in the southern part of the county and deposit them in the landfill it proposes for a per ton "tip fee of $17.70 (Present value as of 6/16/87)," WACOC's Exhibit No. 1, App. 1, p. 13 (emphasis in original), which is to be "adjusted automatically upward or downward to reflect the change in Consumer Price Index." Id. The County guarantees WACOC 275 tons per day and pledges to "exercise its best efforts to insure that all the Solid Waste generated within the County will be delivered to one of the designated transfer stations or the landfill," WACOC's Exhibit No. 1, App. 1, p. 8, for the next thirty years. At present, the County generates "including the municipality . . . about 525-550 tons a day." (T. 61) The County agrees to cooperate "to obtain financing of the real property and equipment necessary [for WACOC] to perform . . . by a proposed bond issue." WACOC's Exhibit No. 1, App. 1, p. 14. To this end, the county commission adopted a resolution authorizing issuance of industrial revenue bonds in accordance with Chapter 159, Florida Statutes, in an amount not to exceed $8,000,000. Alternatively, and perhaps more in keeping with current tax law, "it's going to one of the larger financial institutions like Merrill Lynch Pierce Fenner & Smith or someone like that and actually a bond issue through them, non-industrial," (T.74) or so WACOC intends. Phase I Designed to receive Okaloosa County's solid waste for five years, Phase I is to occupy a site on the eastern slope of a small hill between the east and west branches of Mare Creek, which converge in Fawn Lake, north of the property on which WACOC has options. Water flows out of Fawn Lake into a no longer bifurcated Mare Creek (which was dammed to create the lake), and ultimately into the Shoal River, more than 3,000 feet from the site. By rule, DER has designated Shoal River outstanding Florida waters. Fawn Lake and Mare Creek are Class III surface waters. The Phase I site is "zoned for agricultural uses, which was determined by the Okaloosa County attorney to be appropriate for a landfill." Prehearing Stipulation, p. 7, No. 5. "The county attorney's determination has not been ratified by the County Commissioners." Id. Site Geology "Subsurface conditions have obviously a tremendous effect on the design of the landfill." (T.592) "[A] site's geological and hydrological characteristics are relevant to its potential for contamination." Prehearing Stipulation, p.7, No.4. Throughout the 1760-acre site, beneath a thin topsoil and root mat layer, the site soils consist of clean loose sands to an average depth of about 8 feet below ground surface. . . . From a depth of about 8 feet to 18 feet, a layer of dense orange clayey medium to fine sand (with some coarse sand and fine gravel) covers most of the proposed landfill site. . . . Beneath the clayey sand unit are loose and dense . . . sands . . . . WACOC's Exhibit No. 1, Appendix B. The clayey sand unit occurring underneath the loose, Pliocene sands on the surface is part of the Citronelle formation, which "characteristically changes abruptly over very short distances." (TB. 29) The Citronelle consists "principally of quartz sand, with numerous beds, stringers and lenses of clay and gravel." CCE's Exhibit No. 21, p. 33. "The soils on the site standing alo[ne] would not be sufficient for a liner." I.T. 559 WACOC's expert reported an "average vertical hydraulic conductivity for [the upper Citronelle of] . . . 6.2 x 10-7 cm/sec (1.7 x 10-3 feet/day)." Laboratory tests on soil samples, taken more than eight and less than 18 feet below the surface of the site proposed for Phase I, demonstrated the variability of the sands making up the upper portion of the Citronelle formation on site. The percent finer than the U.S. No. 200 mesh sieve (silt and clay size fraction) . . . ranges between 17.5% to 41.7% . . . . "Vertical hydraulic conductivities for . . . [deeper] sands [on which waste disposal cell liners are to be laid] range from approximately 2.7 x 10-5 cm/sec to 5.8 x 10-4 cm/sec (0.08 to 1.62 feet/day)." Id. The variability of fines contents among samples reflects variability in hydraulic conductivity in the upper Citronelle, as well. This variability explains why an average permeability or vertical conductivity figure for the clayey sands in the upper Citronelle is of limited use in predicting how quickly rainwater will move through it, if these sands are used to cap the landfill after its completion, as proposed. Samples taken from eleven borings made throughout the entire 1,760-acre site were the basis for the applicant's average vertical hydraulic conductivity number. Only one of the borings was done on the Phase I site itself. If a ten-foot thick, continuous layer of clayey sands with a vertical conductivity of 6.2 x 10-7 centimeters per second occurred eight feet beneath the surface, the overlying Pliocene sands would hold a water table year round, given the high rainfall in the area. In fact, the applicants' consultants reported a water table on the Phase I site 21 to 30 feet down, beneath or within, but not above, the clayey sands in the upper Citronelle, in February of 1988. (T.595) The higher water tables observed in October of 1988 were also below the loose surficial sands. This demonstrates a vertical hydraulic conductivity for the upper Citronelle beneath the site proposed for Phase I well above the reported average. A borrow pit, off site but nearby, illustrates the fallacy of relying on average conductivity values to predict the movement of water. At the upper end of the excavation, a seep emerges from the sand to form a stream that flows 40 or 50 feet across red clayey materials resembling those on site, then sinks, disappearing into the earth. Even the value assigned to a particular split spoon sample may be a misleading average. B.T.126-7. Preliminary Plans Drawn In Phase I, WACOC proposes to excavate three different areas or cells for solid waste disposal "to approximately 20 feet below natural grade." (T.116) Accepting information they were furnished, the design engineers made the important (T.172) but erroneous assumption that the water table on site fluctuates only within a range "from five to fifteen feet" (T.132) below that. The plan is to fill each cell with solid waste and covering layers of various soils to a height 90 feet above existing grade. Trees growing within the 300- foot green belt planned for the perimeter of the 1,760-acre site would shield the landfill from the view of motorists on U.S. Highway 90. Separated from each other by berms, cells 1 (520' x 520') and 2 (520' x 650') would abut each other south of cell 3 (480' x 1170'), with another set of berms circumscribing all three cells. The bottom of each cell is to have a gradual V-shape, sloping "approximately one percent in the longitudinal direction and two percent in the traverse direction[s]," (T.116) toward the centerline. The plans call for compaction of the soils, once excavation has been accomplished, and for "root pickers" to remove rocks, roots and any other sharp objects. The plans do not contemplate the use of sieves. WACOC proposes to line these pits by covering the naturally occurring, compacted soils with a 1.5 millimeter (60 mil) layer of high density polyethylene, a plastic which has been manufactured for use in land fill liners at least since 1982. (T.401) The purpose of lining landfills is to contain contaminated water that would otherwise escape into the environment. Rain percolating through solid waste, together with moisture already in the solid waste at the time it is deposited in the landfill, leaches chemicals from the waste, producing a toxic solution called leachate. Products of industry make their way into household garbage and the municipal waste stream. About two percent of waste that reaches municipal sanitary landfills consists of materials which, if generated industrially in quantity could not lawfully be disposed of, except as hazardous waste. Scientists have "found municipal waste landfill leachates that were as toxic as those from Love Canal." (IT.696) Gundle Liner WACOC has decided to obtain a liner which meets minimum requirements of the National Sanitation Foundation Standard Number 54, Flexible Membrane Liners, November, 1983, from Gundle Lining Systems, Inc. (Gundle). "All Gundle materials are available in 22 1/2' widths with no factory seams " WACOC's Exhibit No. 7. Gundle's own employees would unroll the plastic, position it using "tack welding" to form a continuous sheet, join the strips with extrusion welds, inspect the seams visually, perform destructive "shear and peel tests . . . by random selection no less than the [to be] agreed [but unspecified at hearing] frequency . . . . [and conduct v]acuum testing [which] follows no specific standard." WACOC's Exhibit No. 7, Enclosure 6. (T.403, 411- 2) As a condition of the permit (No. 26), DER would require that an independent third party, a registered professional engineer, participate in quality assurance. High density polyethylene's "chemical resistance and durability. . . . enable[ Gundle] . . . to offer a 20-year warranty . . . for both the product and installation." (T.404) Gundle's liability under the warranty depends on how many years remain under warranty and "shall in no event exceed the amount of the sale price." (IT.434) The warranty excludes "any liability for consequential damages arising from the loss of . . . product owing to the failure of the material or installation," id.; CCE's Exhibit No. 3, and any liability whatsoever in the event of acts of God, including floods, and "excessive pressure or stress from any source." CCE's Exhibit No. 3; (IT.432). While the material may well outlast the warranty, perhaps by decades, in "geological time," it will inevitably fail. In the short term, too, the integrity of liners like that proposed is highly problematic. Past problems have included "mechanical damage . . . of one form or another such as with the bulldozer, or if somebody drops something." (IT.429) Here, before the first lift of solid waste (which would not include construction or demolition debris) is placed, four feet of sand (stockpiled during excavation) would be piled on top of the disposal cell liner. A bulldozer's gash might not go unnoticed, but small holes along seams can be missed, despite rigorous quality control measures. At the Ocean County landfill in New Jersey, "there was more liquid . . . than would have been true from the calculated moisture vapor transmission data," (IT.427) but Gundle's chemist testified this might have been "condensation on the soils on the back side of the liner." Id. Leachate Collection Embedded within the sand layer, in the crotch of the V, six-inch, perforated, schedule 80 PVC pipe, wrapped in filter cloth, is designed to collect leachate. The top of the pipe is to be eight inches above the liner, according to the leachate underdrain detail on sheet 15 of WACOC's Exhibit No. One pipe running the length of cell 3 and another running through cells 1 and 2 would move leachate to the leachate trunk line, another (intact) PVC pipe which would, in turn, empty into a paved flume in the leachate collection pond. The pond has been sized to contain the amount of leachate WACOC's consultants originally predicted a 25 year return 24-hour storm would generate, together with the rainfall such an event would deposit in the leachate collection pond, and still leave a foot of freeboard. "You have room below that major storm elevation that holds 60 to 70,000 cubic feet of leachate." I.T. 127. Except for the flume, the leachate pond is to be lined, like the disposal cells, with high density polyethylene. In the leachate collection pond, only 18 inches of sand would overlie the synthetic liner. From time to time, leachate would be pumped from the pond into tank trucks for removal to the Garnier wastewater treatment plant, which has a capacity of 6,500,000 gallons per day. Garnier is specifically permitted to receive only domestic wastewater, but the permit does not forbid industrial wastewater, and the plant now accepts leachate from the Wright landfill. DER has not classified landfill leachate either as domestic or as industrial wastewater. Before accepting it for treatment, the plant might require pretreatment of the leachate, whether on account of its anticipated acidity or for other reasons. If leachate causes sludge from Garnier to exceed standards for heavy metals, the sludge can be deposited in a Class 1 landfill like the one proposed here. WACOC has not yet entered into a contract with Garnier's operator for treatment of leachate. Not until leachate is removed from the leachate collection pond are pumps to be employed. Leachate would have to accumulate on the waste disposal cell liners and enter a pipe, in order to leave the cells. The design specifies perforations along the whole length of leachate collection pipe, around the bottom of the pipe. If the pipes clogged west of the cell walls, leachate could flow through sand and reenter the pipe further downslope. Outside the waste disposal cells, manholes have been planned, to afford access for cleaning the pipes out. The applicant did not demonstrate with calculations that gravity would induce flow through the pipes at a rate sufficient to remove leachate deeper than 12 inches. In the leachate collection pond, which is to be roughly 200 by 500 feet, leachate might attain a depth of several feet, before being pumped into a tank truck. The pond sides are to be lined with high density polyethylene to a height nine feet above the pond bottom. As far as the evidence showed, the depth of leachate in the pond would never fall below 18 inches anywhere on the pond bottom, once leachate began filling the leachate collection pond. Only if leachate were extracted from the sand covering the liner could the leachate head in the pond fall below one foot. The plan is for tank truck operators to place their hoses on "a concrete flume on top of that sand." I.T. 127. Stormwater Management Berms encircling the solid waste disposal cells, together with a series of ditches and culverts, are intended to direct stormwater away from the solid waste to a retention pond for temporary storage and treatment, before discharge offsite. To the extent stormwater which would otherwise flow into solid waste disposal cells can be diverted elsewhere, the volume of leachate can be diminished. The berms also serve to prevent rain falling on solid waste from reaching the stormwater retention pond, or polluting stormwater that does. Lined with relatively impermeable soils, the stormwater retention pond, "a football field wide and two and a half football fields long," (T.201) is designed to be big enough to hold the runoff from a 100 year return storm, leaving two feet of freeboard. In practice, some stormwater would percolate into the ground through unlined ditch bottoms, never reaching the pond. Stormwater that did reach the pond would either evaporate or drain through sidedrains, which are to consist of perforated six-inch PVC pipe, encased in gravel and covered with permeable sand excavated on site. Lining most of the pond's perimeter, this sand would filter water seeping through it from the pond into the side drains. After collecting in an outfall pipe, water draining from the pond would travel 300 or 400 feet, before discharging above grade, near the east branch of Mare Creek. If, as would be likely, sea gull droppings regularly end up in the stormwater retention pond, phosphorous and nitrogen levels in the east branch of Mare Creek and downstream would increase in time. Other Measures Decomposing solid waste produces methane gas. When cell I is completed, vents are to be installed to direct methane gas into the atmosphere above the center of the cell. I.T.140; WACOC's Exhibit No. 1, p.23 and No.9, p.15. "[T]he wind will disperse any gas within the site." I.T.191,221. If sufficient quantities were generated, a gas collection system would be installed. I.T.140. 31 Spotters will try to divert hazardous or infectious waste, and should succeed in the event a hauler tries to dispose of an accurately labelled 55- gallon drum of a hazardous liquid or red-bagged waste from a hospital, but small quantities of gasoline, paint, paint thinners, cleaning fluids and other hazardous materials cannot practically be diverted. At the end of every working day, solid waste is to be covered with a six inch layer of soils from the site. Fences are planned downwind from the working face to collect windblown debris. Closure A landfill is a long-term proposition. Pollutants still leak from Roman landfills dating to 400 A.D. Contemporary landfills and their regulators recognize the importance of capping landfills to minimize infiltration by rainwater (and so production of leachate.) Even though the plans may be revised later, DER requires applicants for landfill construction permits to make plans for closure, before a construction permit is issued. Landfill operators must also make annual contributions to a trust fund to be used to close the landfill and to bear post-closure expenses, which include trucking leachate and monitoring groundwater. WACOC has already established the trust fund and deposited $100. As a condition of operating the landfill over the five years it proposes, WACOC must deposit one fifth of estimated closure and post-closure costs in the trust fund 60 days before beginning to fill, and another fifth annually (30 days after the anniversary date of the initial payment). The cost estimates are subject to revision annually. (I.T. 384, 843-4) Before closing a landfill, the operator must obtain a closure permit. The trust fund is not expected to absorb the costs of cleaning up polluted groundwater, if that should prove necessary. Local governments, which operate many landfills themselves, sometimes step in when problems with privately run landfills develop. ...A leak develops or something that would cost millions of dollars to address it and you don't have the insurance, you're out of business instantly. ...[WACOC's ability] to address a catastrophic situation that could develop with this is limited to how much capital they have. * * * ...[I]f you don't have some insurance, even if its $500,000 deductible,...if the problem occurs, you're gone. And if you don't have the capital to handle it, it will fall back in the taxpayer's lap which is typically what happens... . (II.T. 70-71) As WACOC's proposed finding of fact No. 12 concedes, WACOC's "liabilities are considerably in excess of its assets." Landfill operators are under no obligation to contract for environmental liability insurance, which is not readily available, in any event. WACOC proposes to cap Phase I with clayey sands excavated on site. The clay required to cap Phase I amounts to "ten acres of the surface by four feet deep, or one acre 41 feet deep." (II.T. 36) WACOC proposes to spread this quantity over all three cells, covering them with an 18-inch clayey sand blanket. On top of that, WACOC would place 18 inches of surficial sand and, finally, six inches of topsoil. The sands are readily available on site, but there is no topsoil to speak of. The clayey sand WACOC proposes to use as a foundation for the cap is too permeable to constitute an effective barrier. (B.T. 149,158), but WACOC could mix it with clay from off site or some other agent to render it less conductive of rainwater. The present plans do not call for mixing, however. High Density Polyethylene WACOC is proposing the synthetic liner underneath waste disposal cells and the leachate collection pond not as one component of a composite liner, (T.158) but as "the state of the art," (T.153) in and of itself. But "flaws in liners are a common occurrence." (IT. 698) After a liner has been laid down and covered with sand, "inadvertent cuts and nicks of unexplained origin" (IT.699) can and do occur. However conscientious, laborers hired as "root pickers" may miss an occasional rock. The plans only call for removal of objects larger than a quarter inch. High density polyethylene is a plastic. If laid over stone or other protuberances, "the plastic will flow away from that pressure point and eventually you will have a hole in the plastic." Id. An investigator examining 60 mil high density polyethylene used as landfill liner "found six pin-holes per acre, mostly associated with the seams, [an] average of 9.4 cuts [per acre] of unexplained origin, [and] 110 [perforations attributable to] rock protu[bera]nces per acre." (IT.705) In an EPA sponsored study, a liner manufacturer installed and third parties "did a careful job of inspecting," id., twelve "rather small" (IT.706) waste disposal cells. Eight of the twelve leaked. Even if holes did not let leachate escape, several carcinogenic, teratogenic, and mutagenic organic constituents of municipal waste leachate dissolve in liners like the one WACOC proposes, "diffuse through and are released on the other side." (IT.699) High density polyethylene is practically impervious to water: water vapor can move through it only at a rate of 1 x 10- 13 centimeters per second. But certain hydrophobic substances, including chlorinated hydrocarbons such as trichloroethylene and vinyl chloride, move readily through high density polyethylene, itself a "very hydrophobic material." (T.807) William T. Cooper, a chemistry professor who participated in developing DER's drinking water standards, appearing in this case as a witness for the objectors, testified: [O]ne of the major problems in doing this work [concerning organic pollutants in groundwater] is establishing . . . standards. In other words, we had to pollute water in a well defined way so that our machines would tell us there was a certain amount of pollution in the water. . . . . . . [W]e started using [p]olyethylene tubes into which we would put several different organic molecules for the very reason that these molecules diffuse so readily through the [p]olyethylene tubes that we could control the rate in which we were contaminating water for laboratory purposes. (IT.806) In order to calibrate their instruments, the scientists who developed drinking water standards for Florida relied on polyethylene containers' ability to transmit organic pollutants in solution inside a container to the water outside at a steady, predictable rate. Chemists think of polyethylene "as a condensed liquid . . . . [because] it has the ability to absorb molecules." (T.807) Water and polyethylene do not mix, however, just as oil and water do not; they are said to be immiscible and to form separate phases. When a third substance is dissolved in either of two immiscibles occurring together, the additive's molecules move between the two phases until equilibrium is reached. The concentration in one phase will differ from the concentration in the other, and both concentrations will depend on the amount of the additive introduced (until saturation), but the ratio of the two concentrations (the "distribution ratio" or "partition coefficient") will always be the same, at equilibrium. A chemist in Gundle's employ testified that any "organic solvents in the leachate . . . would tend to float on the aqueous phase." (T.406) But some hydrophobic organics, including trichloroethylene, are denser than water and would not float. (IT.831) Mr. Cadwallader, Gundle's chemist, conceded that organic materials are soluble in water "to a point of saturation, which typically is not very high . . . ." (T.425) The leachate's nonaqueous phase would occur to some extent, perhaps entirely, within the polyethylene liner. In this connection, the objectors' chemists' opinion, which Dr. Brown also shared, has been credited. For the same reasons Mr. Cadwallader "agree[d] that a liner would gain weight when it is immersed in a pure organic solution," (T423) the liner would swell, as a variety of organic pollutants diffused into it from the leachate. Such swelling has been reported in low density polyethylene. WACOC's Exhibit No. 18. With groundwater in contact with the outside of the liner, the organic pollutants with which the liner was swollen would diffuse into the groundwater, until groundwater touching the liner acquired organic pollutants in the same concentrations in which they occurred in the aqueous phase of the leachate standing on the liner. It is even possible that concentrations of certain hydrophobic organics would be higher outside the liner than inside. (IT.818) If indeed a nonaqueous phase floated on top of the leachate, it would serve to replenish the aqueous phase, as hydrophobic organics diffused into the liner to replace those diffusing out of the liner into the groundwater or soils on the other side. (IT.831) Site Hydrogeology Groundwater flow "mirrors the topography of the site." WACOC's Exhibit No. 1, Appendix B, p.6. On the Phase I site, it flows to the north and the northeast, toward the east branch of Mare Creek. At monitoring well 1, the flow is "about a 45-degree angle down and to the east northeast." B.T.119. Lining the disposal cells and the leachate collection pond with high density polyethylene would curtail recharge (and evapotranspiration) under the cells and the pond. The plan is to line the stormwater retention pond with the same clayey sands that fail to hold a water table. B.T.175 Percolation from stormwater ditches or, despite its lining, even from the retention pond might cause slight mounding of the groundwater under those structures. But construction of Phase I would not appreciably alter the general direction of the groundwater flow. To the extent mounding occurs beneath the stormwater retention pond, groundwater table elevations under proposed cell 3 would be higher than they otherwise would have been. Elsewhere, the cell liners should have the effect of lowering groundwater elevations below what they would otherwise have been, ignoring infiltration from stormwater ditches. Any changes may be very slight, since groundwater from recharge areas upslope apparently flows under the site. In February of 1988, piezometers were used to measure water table elevations on the Phase I site. Distance between elevations proposed for liners and the February 1988 water table varied, but were no less than nine feet at any point measured. Based on the February 1988 measurements, the design engineers assumed an unsaturated zone 25 to 30 feet thick. But, on October 11, 1988, the second day of hearing, the same piezometers (B.T. 19) disclosed much higher water table elevations. Near the creek, the water table had risen only 4.92 feet higher than it had been in February, but in the wells closest to cell 1, the October water table exceeded the February elevations by 11.33 and 11.41 feet. (B.T. 40) On October 11, 1988, the water table was "above the bottom of the liner of the proposed landfill in cell two, portions of cell two, a lot of it, portions of cell one and a corner of cell three," (B.T. 44) with "about two feet of water above the proposed liner in the corner of cell two." Id. The levels may have been considerably higher in September. Since periodic measurements have not been taken over the requisite year or two, the seasonal high water table on the Phase I site has not been determined. The height of the groundwater table depends on how quickly rainwater percolates down to the water table to replace groundwater lost to evapotranspirtation or subterranean flow offsite. Groundwater under the Phase I site discharges into the east branch of Mare Creek. The timing as well as the amount of rainfall figure in, because once the soils are saturated, rain runs off instead of infiltrating. Still monthly rainfall is a good indicator of how much water has percolated down to recharge an aquifer. No records of rainfall on the site itself exist, but statistics from sites not far away show that extraordinarily high rainfall in September of 1988 contributed to the groundwater elevations measured on October 11, 1988. At one or more wells on site, the water table dropped another foot between October 18 and October 26, 1988. CCE's Exhibit No. 36. Rainfall data suggest that in most years, "the actual peak high for a water table probably would be towards the end of August." (B.T. 95) At present, the surficial aquifer beneath the proposed landfill site contains potable water. People living in the area draw water from the surficial aquifer for drinking water purposes, in one case from a well only some 30 feet deep. The nearest well to Phase I is 3,000 feet away, on the other side of the east branch of Mare Creek. The surficial aquifer goes all the way down to the Alum Bluff group, 75 feet below ground. Saltwater intrusion threatens in southern Okaloosa County. By 1995, if its growth continues at the present rate, the City of Destin will require another, supplementary water supply. Plans to tap the Floridan in northern Okaloosa County include well fields in the Eglin Air Force Base area and north of Freeport. But the Floridan "won't supply all the future projected needs." (II.T. 16) Desalinization is expensive. Eventually Okaloosa County is "going to have to look further toward the use of surficial water," (II.T. 13) as a public water supply. Leachate Characteristics Leachate from municipal landfills has high biological oxygen demand, high salt content, and significant concentrations of metals and organics. (I.T. 699) Cleaning solvents, oil-based paint, furniture polish, spot removers, xylene, toluene and benzene are among common constituents of municipal waste. Lisa Stewart, who picks up garbage in northern Okaloosa County four days a week, has noticed "containers containing a substance" (II.T.137) bearing such labels as naphtha, methylene chloride, toluol, burnt motor oil, insecticides, fungicides, trichloroethane, oxalic acid, xylol, petroleum distillates, polyglycol ether, plasticizers, sulfuric acid, methanol, ethanol and sodium hydroxide. Scientists have found every chemical DER lists on its "primary or secondary water quality standard numeric list" (I.T. 697) in municipal leachate, as well as "about 20 chemicals that are known to [b]e carcinogenic, mutagenic or teratogenic which are not on that list." Id. At least some of this latter group can be anticipated at the proposed landfill, if it is built. The organic materials degrade only slowly; they have half-lives ranging from 20 to 50 years. (I.T. 698) Biochemical oxygen demand accounts for most of the stench to be expected from leachate standing in the leachate collection pond. The "combination . . . of hazardous waste from small quantity generators and from households we would expect to be somewhere in the range of five to 10,000 tons per year." (T.T.148) In order to predict the amount of leachate to expect, experts on both sides resorted to a mathematical model, known acronymically as HELP, for "Hydrological Evaluation Landfill Program." (T.689) These experts made assumptions about annual rainfall, the permeability of the cap materials which, after their initial excavation and stockpiling are destined to do double duty as a final cover for the landfill, and other factors, in order to calculate the amount of leachate likely to accumulate above the liner. WACOC's consultants calculated a head of 2.4 inches, assuming annual rainfall of 68 inches, and an unrealistically low permeability for the clayey sands under the Phase I site which are to be used for capping the Phase I cells as they attain their design heights of 90 feet above grade. Using WACOC's average vertical conductivity figure for the clayey sands of 6.2 X 10-7, without changing any other assumptions WACOC made in running the HELP model, yields a leachate head of 8.5 inches. Even if it were appropriate to use an average, this figure is low, because the permeability of materials recompacted in a laboratory is ordinarily ten times less than when the same material is compacted in the field. Here compaction "in the field" would occur on top of a mound of garbage. "[T]he system will be spongy." (I.T. 752) The HELP model makes no allowance for cracks in the cap, which are bound to occur, if WACOC closes the landfill as it proposes. As garbage degrades, it settles and sinks. This would cause shear planes or faults in the clayey sand cap, which cannot readily be detected, buried beneath sand, topsoil and vegetation. Estimating conservatively, "we could be dealing with twice as much water as we're calculating from the HELP model due simply to cracks in the facility." (I.T. 692) During those periods when the groundwater table is above the bottom of the disposal cell liners, groundwater infiltration through such imperfections as exist in submerged portions of the liners will increase leachate volume. Ignoring groundwater intrusion, cell 1 alone should produce 5,000 gallons a day of leachate the first year after closure. (I.T. 510-1). The applicant's own revised HELP model calculations put the leachate head at more than eight inches in a year in which rainfall on the site exceeded the annual average at Crestview by only eight percent (68 inches vs. 63 inches). A foot or more of head annually can be expected, taking into account cracks in the clay cap. Water Quality Monitoring WACOC's groundwater monitoring plan calls for a single well south and upgradient of the Phase I site to monitor "background" groundwater conditions, and a series of monitoring wells east and north of the site designed to detect any groundwater contamination the landfill may cause. WACOC's Exhibit No. 9, Sheet 11. Four of these downgradient wells would be placed by the eastern perimeter of the zone of discharge to measure compliance with DER's numeric water quality standards at that edge of the zone. Four other wells are planned within the zone of discharge. In addition, surface waters are to be monitored at seven points, five on the east branch of Mare Creek and two on the west branch, but none further south than the berm separating cell three from cells one and two. WACOC's own employees would take samples, arrange for their analysis and report the results to DER. Among the specified parameters are iron and chloride. As far as the record reveals, testing for sodium in addition would not make for earlier or more reliable leak detection. CCE's Exhibit No. 20. The suggestion that groundwater be tested for calcium assumed montmorillonite in the clayey sands, which the evidence did not show to be present. I.T. 988. According to a DER chemist, however, groundwater samples near landfills should be tested for volatile organic compounds (VOCs) by EPA method 601/602. Since VOCs always appear to be present in landfill leachate and they can be detected in the subparts per billion (ppb) range, the test is a particularly sensitive indicator for the presence of organics in landfill leachate. (CCE's Exhibit No. 20, p.2.) Also among the specified parameters is fecal coliform, which makes any other routine testing for bacteria superfluous. Given the economic consequences for WACOC if a leak is discovered, it might be well to require WACOC to contract with an independent third party to monitor, in the event the landfill is built. Since groundwater flow on site has a vertical as well as a horizontal component, monitoring requires appropriate placement not only of wells, but also of screens. One approach is to cluster wells so that a succession of screens covers the entire thickness of the aquifer. Monitoring well screens should not exceed 15 feet in length, in order to avoid dilution that might render contaminants indetectable. CCE's Exhibit No. 2. But a hydrogeologist with sufficient information could place screens within transmissive zones through which groundwater flowing underneath the disposal cells or the leachate pond is likely to move. B.T. 136 With respect at least to leachate constituents that do not diffuse through liners, monitoring groundwater to detect pollution is more difficult if a landfill is lined than if it is not, because contaminant plumes are larger if they emanate from larger sources. CCE's Exhibit No. 19. Unless monitoring wells were sunk at ten-foot intervals east and north of where leachate is to collect, it would be easy to miss the plume from a small leak, which might be destined to become a large leak. But even the objectors' experts do not "consider that very practical financially." (B.T. 135) Groundwater Pollution Both through imperfections in the synthetic liner and, as regards hydrophobic organic pollutants with low molecular weights, by diffusion directly through even flawless portions of the liner, pollutants in the leachate will escape into the environment, if WACOC builds the landfill it has proposed for Phase I. As far as can be told from the evidence, the groundwater table would never reach the bottom of the leachate collection pond, so that adsorption and diffusion in soils underneath the pond would attenuate the effect of any leakage there, before it could enter the groundwater. But the soils on site have very low adsorption capacity and very low biological activity. I.T.719 Leachate leaving unlined, northwest Florida landfills five feet above the water table have caused serious pollution problems. The evidence showed that the groundwater table would rise above portions of the lined bottoms of all three waste disposal cells, on which leachate will also be standing. This may occur infrequently, would not necessarily happen every year, and would last for only a few weeks and days at a time, but it was the condition that obtained at the time of the hearing, two months later than seasonal high groundwater should normally occur. When it does happen, "it's entirely possible the leachate will be the same concentration as the groundwater in contact with the bottom of the liner." I.T. 701. In any case, carcinogenic, mutagenic or teratogenic agents (I.T. 697), including up to 20 for which DER has not established numeric limits, would occur in the leachate, and some would enter the groundwater, violating the DER "free from" requirement. I.T. 777. Precise concentrations have not been forecast but, at least at times, over the course of the landfill's existence, the leachate would contain certain mutagenic substances for which no safe lower limit has been established. Nor did the evidence give reasonable assurance that violations of DER's numeric standards pertaining to the trichloroethylenes, the tetrachloroethylenes and vinyl chloride would be unlikely outside the zone of discharge. I.T. 771,781-2. It depends in part on the volume or rate at which leachate or these constituents leak. B.T. 94. The evidence showed they will leak at some rate, even where there are no flaws in the liner. In a test involving higher concentrations of trichlorethylene and other organics than are anticipated here, experimenters observed a "flow rate . . . on the order of 125 gallons per acre per day from concentrated organics." I.T. 702. In 27 acres of plastic, flaws are to be expected. Good intentions notwithstanding, the evidence showed holes in the synthetic liner should be anticipated, and taken into account in designing a landfill. The rate at which leachate will leak through these imperfections depends on their number, shape and size; and, as to each, the depth of the leachate above it and the permeability of the medium below it. A circular hole with a diameter of one- sixteenth of an inch will discharge liquid, standing on top of it a foot deep, at the rate of 70 gallons a day, into air, gravel or porous sand. The rate for a similar hole with a diameter of one-eighth of an inch is 192 gallons per day. In the event of a leak above or near an area like the one into which the seep sank in the borrow pit, the soil would not slow the rate of leakage. (I.T. 718) Otherwise, for a given leachate head, the conductivity of the soil (if unsaturated) would determine the leakage rate. "[T]here will be less depth higher up the liner." I.T.760. But where the liner is lowest and the leachate deepest, the liner will lie over the loose sands that occur beneath the clayey sands. Rating tests demonstrated considerable variability in the hydraulic conductivity of all of the sands tested. Piezometer readings on October 18 and 26, 1988, showed how they transmit water as a unit. In eight days the water table (which is only at atmospheric pressure) fell a foot. The clayey sands would not prevent leachate's leaving the waste disposal cells and entering the groundwater, although in some places (where the leachate has less depth), they would slow the rate of leakage. "We could get tens of thousands of gallons [annually] leaking out of a 27-acre site which this is through holes." (I.T. 707) With groundwater in contact with portions of the liners, the leakage rate there would depend on the relative elevations of the groundwater table and the leachate standing on the liners. If the groundwater table were higher, upward pressure might push groundwater into the disposal cells, disminishing or even preventing leachate leakage until the water table fell below the height of the surface of the leachate. But, when that happened, direct discharge of undiluted leachate can be expected, directly to the groundwater, as long as groundwater abutted a flaw in the liner. DER's rules do not apply the numeric standards underneath or within 100 feet of waste disposal cells, which the rules denominate a "zone of discharge." Whether numeric standards are violated at the edge of the zone of discharge depends not only on the leakage rate, but also on where the leak occurs, on the velocity of the groundwater, and on pollutant concentrations in the leachate. Calculations taking all these factors into account have not been done for WACOC's Phase I. But credible expert testimony predicted such violations would eventually occur outside the zone of discharge. I.T.771. Synthetic liners like the one WACOC proposes are usually placed on top of three feet of highly impermeable, mineralogically suitable clay. "A clay liner...will retain organics to a greater extent than a synthetic liner." I.T. 823. Using it as proposed here, where it would come into direct contact with groundwater, does not give reasonable assurance that groundwater pollution will not occur.
Recommendation It is, accordingly, RECOMMENDED: That DER deny WACOC's application for a permit to construct a class I landfill in Okaloosa County. DONE AND ENTERED this 14th day of April, 1989, in Tallahassee, Florida. ROBERT T. BENTON, II Hearing Officer Division of Administrative Hearings The DeSoto Building 1230 Apalachee Parkway Tallahassee, Florida 32399-1550 (904)488-9675 Filed with the Clerk of the Division of Administrative Hearings this 14th day of April, 1989. APPENDIX DER's proposed findings of fact Nos. 1, 7, 11, 12, 14, 15, 17, 18, 21, 22 except for the last sentence, which is rejected, 23, 24, 25, 32 except for the last sentence, which is rejected, 38, 45, 46, 48, 49 except for the last sentence, which is rejected, 50, 52, 54, 56 except for the last sentence, which is rejected, 57, 58, 59, 60, 62 except for the sentence "DER has no rule prohibiting contact of the liner with ground water," 63, 65, 66 except for the second clause which is rejected, 67, 69, 72, 73, 78, 79, 80, 81, 83 and 85 have been adopted, in substance, insofar as material. With respect to DER's proposed finding of fact No. 2, the intent to issue is dated April 1, 1988. With respect to DER's proposed finding of fact No. 3, financial feasibility was not demonstrated but is not material under the rules. With respect to DER's proposed findings of fact Nos. 4, 5 and 6, closure cost estimates assume the suitability of the clayey sands on site as a cap, which the weight of the evidence did not establish to be the case. With respect to DER's proposed finding of fact No. 8, the use of a high density polyethylene membrane, without more, to keep hydrophobic organic materials out of abutting groundwater is not proven technology, as far as the evidence showed. With respect to DER's proposed finding of fact No. 9, the rules do not require environmental liability insurance. DER's proposed findings of fact Nos. 10, 19, 20, 26, 35, 37, 44, 55, 61, 71, 74, 75, 77, 82, 86 and 87 are rejected as unsupported by the weight of the evidence, without comment. With respect to DER's proposed finding of fact No. 13, the fact that a synthetic liner separates solid waste from the groundwater does not make it permissible to deposit solid waste in groundwater. While the October readings did not prove that groundwater would rise above the sand in which the leachate will collect to touch the solid waste itself, September's rainfall, the rate at which the water table dropped between October 18 and 26, 1988, and the probability of defects in the liner showed that this was a realistic possibility. With respect to DER's proposed finding of fact No. 16, two percent of the materials disposed of in municipal sanitary landfills are hazardous in a chemical, if not legal, sense. With respect to DER's proposed finding of fact No. 27, the "state of the art" use of high density polyethylene liners is as one component of a composite liner, or even as part of a double liner system, at a hydrogeologically suitable location. This material works well for some purposes and not at all for others. With respect to DER's proposed finding of fact No. 28, there was no showing that any other Florida landfill has been placed so as to come into contact with the groundwater table, or that a synthetic liner has ever been used for a landfill without clay; synthetically lined landfills have only recently been installed in Florida, and detection of leaks from lined landfills is difficult. With respect to DER's proposed finding of fact No. 29, since uncontaminated water is not a pollutant, it is not a permeant of concern. With respect to DER's proposed finding of fact No. 30, the evidence showed that under ideal, test conditions, 8 of 12 liners leaked. Under actual field conditions leaks exceeded 100 per acre. The weight of the evidence makes it unreasonable to conclude that 27 acres of plastic can be laid down in Okaloosa County without any flaws. With respect to DER's proposed finding of fact No. 31, the rate of 192 gallons per day assumed gravel or porous sand which offers essentially the same resistance as air; there is no sandy clay anywhere on site, as far as the evidence showed; more than 18 feet below the surface, where most of the liner is to be laid, there are not even clayey sands, according to WACOC's own expert; the sands that do occur there include loose sands with a permeability greater than 4.9 X 10-4; and include numerous gravel beds; the .00022 gallons per day calculation assumes a hole a quarter as large (half the radius of Dr. Brown's) and ignores horizontal hydraulic conductivity. The fact that the water table dropped a foot in about a week demonstrates that the soils cannot be counted on to contain the leachate underneath flaws in the liner. With respect to DER's proposed findings of fact Nos. 33 and 34, Haxo's results were consistent with their conclusions but explicitly not the only basis for them. Gundle's chemist conceded that hydrophobic organic materials diffuse through high density polyethylene. His opinion that an accumulation in the soils on the other side would equalize concentrations and stop further diffusion did not take into account groundwater abutting the liner, and flushing the soils. The liner absorbs materials; but adsorption does not take place there. Transportation and dispersion need not be known as to "free froms." On page I.T. 777, Dr. Brown testified that diffusion would cause violations of DER's regulations, and this testimony has been credited. With respect to DER's proposed finding of fact No. 36, the swelling of the liner with organic materials is evidence of the diffusion which would result in organic materials' entering the groundwater. With respect to DER's proposed findings of fact Nos. 39 and 41, one inch of leachate in all three cells amounts to 2.25 acre feet, which is more than a "little." Calculations have not been done. With respect to DER's proposed findings of fact Nos. 40 and 42, no allowance was made for cracks in the cap material (which cannot be seen under the vegetation, topsoil and drainage sand layer.) With respect to DER's proposed finding of fact No. 43, a much greater leachate head than within the waste disposal cells may occur depending on where the marker is placed, but hydrophobic organics diffusing through the liner and absorbing in the soils would not be flushed out by groundwater. Except for the last sentence, this proposed finding of fact reflects the weight of the evidence. With respect to DER's proposed finding of fact No. 47, some water will evaporate. With respect to DER's proposed finding of fact No. 51, monitoring wells 8 and 9 are both more than 100 feet from waste disposal areas. The evidence did not show that the monitoring wells "can be expected to detect any contamination." With respect to DER's proposed finding of fact No. 53, DER's experience also suggested testing for volatile organic chemicals. With respect to DER's proposed finding of fact No. 64, the rate of decline also suggests that the water table was as higher elevations than those measured. An applicant must give reasonable assurance that pollution in violation of DER rules will not occur under foreseeable, recurring conditions, including during those times the liner is submerged. With respect to DER's proposed finding of fact No. 65, the proposed finding is adopted, as regards physical tears. With respect to DER's proposed finding of fact No. 68, the proposed finding is adopted, except for leakage through the liner, sometimes directly to groundwater. With respect to DER's proposed finding of fact No. 76, clayey sands were not reported below 18 feet. The difficulty with the groundwater monitoring plan is not the soil characterization, but the number of wells. Because synthetic liners leak, clay mineralogy is important to know. No clay is proposed here, however. With respect to DER's proposed finding of fact No. 84, effective odor control would also entail emptying the leachate pond regularly. WACOC's proposed findings of fact Nos. 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 13, 14, 15, 17, 19, 23, 24, 25, 26, 27, 31, 32, 33, 34, 35, 36, 37, 38, 42, 43, 45 50, 58, 61, 64, 66, 70, 71, 72, 75, the first sentence of No. 76, Nos. 78, 79, 80, 81, 82, 83, 85, 86, 87, 88, 90, 92, 93, 94, 96, 97, 99, 100, 101, 102, 103, 104, 105, and the first sentence of 113 have been adopted in substance, insofar as material. With respect to WACOC's proposed finding of fact No. 11, the current tonnage figures appear in the application but their accuracy has not been established by competent evidence. With respect to WACOC's proposed finding of fact No. 12, projected profits depend on various problematic assumptions. With respect to WACOC's proposed finding of fact No. 16, the initial payment was $100. With respect to WACOC's proposed finding of fact No. 18, the cost estimate's reasonableness depends largely on what it would cost to obtain suitable material for a cap, which is not clear. With respect to WACOC's proposed finding of fact No. 20, Scott had independent knowledge of the availability and cost of clay. With respect to WACOC's proposed finding of fact No. 21, the proposed finding accurately reflects the evidence, with the qualification that the layer of dense orange clayey medium to fine sand also contains some coarse sand and fine gravel. With respect to WACOC's proposed finding of fact No. 22, the water table will be below the liner most, but not all, of the time. With respect to WACOC's proposed finding of fact No. 28, see the discussion of DER's proposed finding of fact No. 13. WACOC's proposed findings of fact Nos. 29, 59, 63 and 78 are rejected as contrary to the weight of the evidence, without comment. With respect to WACOC's proposed finding of fact No. 30, hazardous materials will end up in the landfill. With respect to WACOC's proposed finding of fact No. 39, the liner's permeability depends on the permeant. Although it is almost impervious to water, hydrophobic organics move readily through. Clay is a much better liner for those materials. With respect to WACOC's proposed finding of fact No. 40, the Gundle liner by itself is not the state of the art in Florida or anywhere else for municipal sanitary landfills. Proposed conclusions of law are addressed elsewhere. With respect to WACOC's proposed finding of fact No. 41, in the puncture test, the liner withstood a probe exerting 270 ponds of pressure. With respect to WACOC's proposed finding of fact No. 44, there are no clayey sands at the depth proposed for the deeper portions of the waste disposal cell liners, as WACOC's proposed findings of fact Nos. 21 and 27, taken together reflect. With respect to WACOC's proposed finding of fact No. 46, as the manufacturer's representative said, "these liners are a part of the quote unquote state of the art requirement for lined hazardous waste facilities." I.T. 404 (emphasis supplied). The other part is three feet of clay, not sand, underneath. With respect to WACOC's proposed finding of fact No. 47, it depends on the hazardous waste facility. A DER chemist, Mr. Watts, recommended monitoring groundwater near a municipal landfill for volatile organic chemicals. While most municipal garbage is not toxic, leachate from municipal waste is toxic. With respect to WACOC's proposed finding of fact No. 48, the testimony was that the groundwater pollution at Wright landfill was "most likely" from unlined cells. No lined landfill in DER's Northwest District has been built below the groundwater table as far as the evidence showed. With respect to WACOC's proposed finding of fact No. 49, While municipal leachate constituents should not corrode the liner, many can diffuse through it. With respect to WACOC's proposed finding of fact No. 50, some two percent of the waste stream will still be hazardous materials. With respect to WACOC's proposed finding of fact No. 51, some organic materials will sink, rather than float. The sand within which the leachate will accumulate will not extract or absorb organic constituents of the leachate, as far as the evidence showed. With respect to WACOC's proposed finding of fact No. 52, removal is first to the leachate collection pond, also lined with high density polytheylene. With respect to WACOC's proposed finding of fact No. 53, it is wholly improbable that 27 acres of plastic will be installed "without physical flaws." Leakage could exceed 10,000 gallons a year. With respect to WACOC's proposed finding of fact No. 54, not all organic materials diffuse though high density polyethylene. Dr. Haxo's views on WACOC's proposal are not a matter of record. The 448-page EPA Study discusses containment techniques. With respect to WACOC's proposed finding of fact No. 55, the Haxo studies are pertinent although they do not purport to replicate a landfill precisely. In some studies he used concentrations of a single organic that were comparable to the concentrations of organics as a whole in municipal leachate. With respect to WACOC's proposed finding of fact No. 56, direct discharge of leachate into the groundwater, even in small quantities could violate the "free from" standards as could diffusion into the groundwater of carcinogenic, teratogenic or mutagenic, hydrophobic organic materials. With respect to WACOC's proposed finding of fact No. 57, CCE's experts' views about synthetic liners coincided in important respects with those of Gundle's chemist. There is no clayey layer where much of the waste disposal cells' liners are supposed to go. Given the certainty of leakage directly to the groundwater, it is the applicant's burden to do quantative analysis. With respect to WACOC's proposed finding of fact No. 60, there are no data for the site itself. The available data are incomplete. With respect to WACOC's proposed finding of fact No. 62, the February water level is likely to be more common than the October water level. The weight of the evidence did not establish that "under normal conditions the water level should fluctuate no more than five feet." With respect to WACOC's proposed finding of fact No. 64, the proposed finding reflects the evidence except for the final sentence. *** With respect to WACOC's proposed findings of fact Nos. 67, 68 and 69, it is inappropriate to schedule pumpout times at this stage. But it is appropriate to consider above average annual rainfall. Annual leachate production differs from the amount of head at any one time. With respect to WACOC's proposed finding of fact No. 73, the design engineer suggested Roto-Rooter. With respect to WACOC's proposed finding of fact No. 74, intersection should not occur. With respect to WACOC's proposed finding of fact No. 77, municipal landfills are not viewed as hazardous waste generators under federal law. With respect to WACOC's proposed finding of fact No. 82, the second sentence was not proven. With respect to WACOC's proposed finding of fact No. 84, there may be some infiltration. With respect to WACOC's proposed finding of fact No. 89, it would be very expensive to place enough monitoring wells to assure detection of any leaks. Placement of screens should be less of a problem than sinking enough wells. With respect to WACOC's proposed finding of fact No. 91, the Watts memo's suggestion of testing for volatile organic chemicals should give additional assurance. With respect to WACOC's proposed finding of fact No. 95, two percent of the waste stream can be anticipated to consist of hazardous materials. With respect to WACOC's proposed findings of fact Nos. 106, 107, 108 and 109, the proposed clayey sand materials used in the thickness proposed would not create the barrier claimed. Modifications not proposed in the application are possible. With respect to WACOC's proposed findings of fact Nos. 110, 111 and 112, WACOC has not given reasonable assurance that pollution of the groundwater in violation of DER water quality standards would not occur; or that no more than a foot of leachate would stand on the liner. COPIES FURNISHED: Herbert H. Huelsman Anna M. Huelsman 608 Ironwood Drive Fort Walton, FL 32548 Debra Swim, Esquire 1323 Diamond Street Tallahassee, Florida 32301 Bruce A. McDonald, Esquire Post Office Box 887 Mary Esther, Florida 32569 William L. Hyde, Esquire Roberts, Baggett, Laface & Richard Post Office Drawer 1838 Tallahassee, Florida 32302 Chris McGuire, Esquire Department of Environmental Regulation Twin Towers Office Building 2600 Blair Stone Road Tallahassee, Florida 32399-2400 Dale H. Twachtmann, Secretary Department of Environmental Regulation 2600 Blair Stone Road Tallahassee, FL 32399-2400 =================================================================
Findings Of Fact On April 29, 1983, the Respondent Waste Aides Systems, Inc. (hereafter referred to as Waste Aides), filed with the Department of Environmental Regulation (Hereafter referred to as DER) an application to construct and operate a solid waste transfer station. The proposed transfer station would be located at the site of an existing solid waste landfill at Ridge Road and Landfill Road, New Port Richey, Florida. On May 24, 1983, DER, by letter to Waste Aides, requested additional information concerning the permit application and seeking further assurances with regard to control of wash down water and storm water runoff. On June 7, 1993, Waste Aides, by letter provided the additional information, and on June 14, 1983, DEP issued a letter of intent to issue the permit to Waste Aides. The proposed facility is to be located on a parcel of land previously used as a solid waste landfill, but the area where the facility is to be built is not a previously filled solid waste area. The proposed facility will utilize a building which is enclosed on the south, east, and west, and open to the north. The building will be approximately 120 feet wide, 48 feet deep, and 31 to 34 feet high. The general operation of the facility will be to transfer residential and commercial solid waste from garbage trucks to large tractor-trailer trucks for transport to a more isolated solid waste landfill. The facility will not accept hazardous waste or heavy industrial waste. The solid waste will be transported to the facility in garbage trucks. The solid waste will be dumped on a concrete floor inside the building and will then be pushed into a loading chute which sits directly above a waiting trailer. Once the trailer is filled, the solid waste is then transported to an offsite landfill where it is ultimately disposed of. Security at the facility will be accomplished through fencing and gates. The entire property is surrounded by a fence. A gate will be placed at Ridge Road, and a second gate will be installed at the entrance to the property itself. No unauthorized vehicles will be permitted to enter the property or unload solid waste at the facility. The facility will be equipped with two fire control hoses located on the east and west walls of the building. Potable water will be provided to the facility through a hookup to a 16-inch water main at Ridge Road. The facility will have impact sprinklers and spray bars inside the loading chute. Each vehicle on site will be equipped with a fire extinguisher, and two portable fir extinguishers will be located inside the building at appropriate locations. The impact sprinklers will also be utilized for dust control. Each vehicle on site will be equipped with a two-way radio which provides contact with the administrative office and maintenance area of the applicant. The phone in the cardboard recycling facility located on the same property of the proposed facility will be available for use by the operator of other employees of the transfer facility. The recycling facility is owned and operated by the applicant and is directly adjacent to the proposed transfer facility. The operator will be responsible for keeping records of materials handled by the facility. A recordation of volume will be measured and entered as collection trucks discharge their contents at the facility. A scale will be built into the loading area of the transfer trailers, and the weight of all refuse transferred will be recorded by load on a daily basis. These records will be open during normal business hours for inspection by DER representatives, health inspectors, and other authorized regulatory and enforcement agencies. The transfer station operator will be the foreman of the facility and will be present during all hours of operation. The tractor-trailer operator and the operators of the garbage trucks will be present at the facility during unloading and loading. Two or three other employees will also be present on the grounds at varying times for cleanup, grounds work, and other duties at the facility. The facility will be visited and checked approximately twice daily by William R. Peterson and his brother, the owners and operators of the proposed facility. The applicant has available personnel presently in the employment of the applicant, who is a certified driving instructor and who is skilled in the instruction of safe and efficient operating procedures. Additionally, Waste Aides will provide instructions in first-Aides procedures by a person presently employed who is a trained emergency medical technician. Debris will be controlled by certain mechanisms built into the design of the building and by certain operational procedures that will be observed by the transfer station operator. The tipping floor where solid waste is discharged will be enclosed on three sides. When the solid waste is discharged onto the tipping floor, it is immediately pushed into a chute which allows it to fall into the waiting transfer trailer. There is approximately an 8-inch tolerance between the chute and the top of the trailer, and the chute has been designed to angle in toward the trailer so that solid waste will be directed into the trailer to avoid spillage. Additionally, a rubber or fabric membrane will encircle the chute so that when the transfer trailer drives beneath it, the membrane will be inside the transfer trailer, thus directing all solid waste into the trailer itself. An additional benefit of this design is that it will avoid the possibility of drafts of air blowing refuse in the trailer over its sides. The trailer area itself is depressed and thus out of the direct wind stream. Drafts are further buffered by vegetation windbreaks consisting of trees and shrubs located on the west and south sides of the building and by the topographical nature of the surrounding lands on the other two sides. The entire area of the transfer station is fenced as a final barrier to debris escaping the transfer station site. The refuse will normally be on the tipping floor a very short period of time because of the fact that it will be pushed into the transfer trailer immediately upon discharged from the collection vehicle. The refuse, as it is discharged from the collection vehicle, does not lend itself to a debris problem in that it is in a compressed state and tends to remain in a semifragmented mass until it is moved into the trailer. The entire transfer station and surrounding grounds will be cleaned at the end of each day by the station operator. The station will be operated at all times to be in compliance with the applicable noise regulation and ordinances of Pasco County. For noise abatement, Waste Aides has designed the building with noise control in mind. The tipping floor will be constructed with steel rails imbedded in the concrete to eliminate the noise of the front-loading metal bucket scraping on the concrete surface. Six-foot walls buffet all sides of the tipping floor except the north side. The north side is open to an approximate 10-acre tract which was the previous landfill site and will be unoccupied. The tipping floor is enclosed by a building which will provide a significant amount of noise control in a and of itself. There are vegetation screening barriers and earthen berms on the north, west, and south boundaries of the site. The berms will be covered with mature vegetation and will act a both a noise and visual barrier for the site. All equipment used in the operation will meet all county, state, and federal operational decible standards. Odor control will be provided primarily by operational standards which will emphasize the rapid removal of refuse from the site. All refuse will be removed daily except for the possibility of partially filled trailers remaining overnight on site. Should a transfer trailer be required to remain on the site overnight, it will be driven inside the building not less than every 48 hours or in accordance with an approved DER schedule. The tipping floor will be completely cleaned at the end of each workday by being swept broom-clean and then washed down with hoses. When the floor is washed down, the water and debris will flow along the sloped floor to a grid system which will direct the flow into a sand trap and a grease trap and then into a septic tank. The traps will be checked each day after wash down and will be cleaned periodically. The building has been designed in such a manner that no square corner will exist for the possible buildup of refuse. These same operational procedures and design features will discourage any attraction to vermin or birds. Similar transfer station operations in Florida have not experienced the vermin and odor problems typically associated with landfill site operations. The prosed facility will have electric service available. Shelter as well as hand-washing and toilet facilities are available for employees for the facility at the adjacent recycling building. Maintenance on trucks and other equipment will be performed at the applicant's maintenance area located on Osteen Road, approximately 1 to 1 1/2 miles from the proposed facility. Although the proposed facility is surrounded by developed residential areas, the property which is directly contiguous to the property where the proposed facility will be located remains undeveloped. The objectors' travel- trailer park is the closest developed area, and the distance from the nearest trailer to the proposed facility is approximately 950 feet. The design and proposed operation of the transfer station meets or exceeds the criteria contained in Rule 17-7.09, Florida Adminstative Code. Numerous residents in the area object to the location of a garbage transfer station. Their objections are based upon their experience with odor, vermin, birds, and litter experienced in connection with the landfill operation. However, the uncontradicted evidence established that those problems will not exist to any substantial degree in connection with the operation of the proposed garbage transfer station.
Recommendation Based upon the foregoing findings of fact and conclusions of law, it is RECOMMENDED That the Department of Environmental Regulation issue a permit to Waste Aides Systems, Inc., for the construction and operation of the proposed transfer station, subject to the specific conditions contained in DER's Notice of Intent. RECOMMENDED this 4th day of January, 1984, in Tallahassee, Florida. MARVIN E. CHAVIS Hearing Officer Division of Administrative Hearings 2009 Apalachee Parkway Tallahassee, Florida 32301 (904) 488-9675 Filed with the Clerk of the Division of Administrative Hearings this 4th day of January, 1984. COPIES FURNISHED: Harvey v. Delzer, Esquire Post Office Box 279 Port Richey, Florida Douglas H. MacLaughlin, Esquire Assistant General Counsel 2600 Blair Stone Road Tallahassee, Florida 32301 John G. Hubbard, Esquire Post Office Box 1170 Dunedin, Florida 33528 Ms. Victorai Tschinkel Secretary Department of Environmental Regulation 2600 Blair Stone Road Tallahassee, Florida 32301 ================================================================= AGENCY FINAL ORDER ================================================================= DEPARTMENT OF ENVIRONMENTAL REGULATION ORCHID LAKE VILLAGE CIVIC ASSOCIATION, et al., Petitioners, v. OGC Case No. 83-0363 DOAH Case No. 83-2155 WASTE AIDES SYSTEMS, INC., and STATE OF FLORIDA DEPARTMENT OF ENVIRONMENTAL REGULATION, Respondents. /
The Issue The issue in this case is whether the Florida Department of Environmental Protection (agency or DEP) should issue renewal permit No. SO36-26769E to Waste Management, Inc., of Florida (WMI) for the operation of an existing Class I landfill, the Gulf Coast Sanitary Landfill (GCSL) in Lee County, Florida. In the prehearing stipulation, Petitioners specifically dispute whether WMI has provided reasonable assurances: (1) regarding control of off-site odors emanating from the landfill, (2) that it has an approved closure plan, and (3) that leachate from the landfill will not pollute the air and water.
Findings Of Fact The Parties The applicant, WMI, provides waste management services in the state of Florida. These activities include the hauling, transfer, and recycling of solid waste, as well as the construction and operation of landfills. WMI operates GCSL, the facility that is the subject of the permit application, in Lee County, Florida. WCI is a Delaware limited partnership engaged in the business of developing multiple use communities in Southwest Florida. It owns or holds options to purchase lands adjacent to or near GCSL. WCI is also the developer of a planned unit development known as Gateway, which includes residential and commercial properties in close proximity to the landfill. George Sanders owns, personally or as trustee, lands adjacent to or near GCSL. Lee County is a political subdivision of the state with statutory responsibility to plan for and provide efficient, environmentally acceptable solid waste management. Lee County has contracted with WMI to provide solid waste disposal services to citizens of Lee County at GCSL. DEP is the agency of the state with statutory responsibility to regulate and permit landfills such as GCSL. As stipulated, the Petitioners and Intervenor have standing in this proceeding. The Landfill Facility The GCSL is a Class I landfill located at 11990 State Road 82, East, in Lee County, Florida, east of Interstate I-75. The landfill is in a remote, undeveloped area and has been in operation for over 20 years. The Gateway development is south of the landfill. The GCSL includes three parcels of land that have been used for the disposal of solid waste. Parcel 1 and Parcel 2, each about 40 acres, are unlined Class I landfills that have been closed and no longer receive any solid waste. Neither liners nor leachate collection were required when these parcels were constructed and operated. Parcel 3 is a lined Class I landfill that is approximately 80 acres in size. Approximately 50 acres of Parcel 3 are closed and have received final cover. Approximately 30 acres still are used for the disposal of solid waste. Parcel 3 was constructed in phases. In 1984, the Department issued a permit authorizing the construction of the "east hill" and "west hill"--i.e., two separate disposal areas in Parcel 3 where solid waste was placed above grade. In 1989, the Department issued a permit authorizing the construction of the "valley fill"--i.e., a disposal area where solid waste was used to fill in the valley between the east hill and the west hill. Parcel 3 now consists of a single mound of solid waste. As each phase of Parcel 3 was developed, liners and leachate collection systems were installed in Parcel 3 before the commencement of solid waste disposal operations. The liners and leachate collection systems met or exceeded all of the applicable regulatory requirements that were in effect at the time when the waste disposal areas were permitted. Parcel 3 is a well-designed, well-constructed, and well-operated landfill. William Krumbholz is in charge of landfill compliance and enforcement at DEP's district in Ft. Myers. He reports that the GCSL has an "exceptional operation record," and the GCSL is the "best operated Class I landfill" in the district. The GCSL currently is subject to a DEP operation permit (DEP file number S036-180572), as modified. On March 21, 1995, WMI filed an application for a renewal of its operation permit. On or about September 25, 1996, DEP issued its notice of intent to issue the permit to WMI. If issued, the permit would allow WMI to operate the GCSL for an additional five years. See Rule 62-701.330(2), Florida Administrative Code. The landfill is not yet at design capacity and is not expected to reach that capacity during the next five years. WMI desires to renew the operation permit for the GCSL because WMI wishes to continue to provide solid waste management services to Lee County, consistent with WMI's contractual agreement to do so. WMI also wishes to continue operating the GCSL in order to construct Parcel 3 to its final design grades for closure. The design grades will maximize the site's ability to shed stormwater and thus minimize the production of leachate. Continuing to build Parcel 3 to its design grades is environmentally preferable to closing Parcel 3 at this time in its present configuration. Prior to 1994, the GCSL received approximately 1000 tons of municipal solid waste each day. Approximately 90 per cent of the solid waste was household garbage and about 10 per cent was construction and demolition (C&D) debris. The GCSL did not receive industrial waste. The composition of the waste stream changed in August 1994, when Lee County began to operate a waste-to-energy facility. All of the household garbage generated in the incorporated and unincorporated areas of Lee County is taken to the Lee County waste-to-energy facility, where it is burned, and the ash residue is taken to the GCSL. Currently, the GCSL receives only about 450 tons per day of solid waste, which consists of 65-70 per cent ash residue from the waste-to-energy facility, 30-35 per cent C&D debris, and approximately 2-5 per cent municipal solid waste. DEP would allow WMI to accept more solid waste at the GCSL. However, Lee County has the contractual right with WMI to dictate the types of materials deposited in the GCSL, and it is the county's intent to use the waste-to-energy facility, not the GCSL, for the disposal of putrescible wastes. Lee County is contractually obligated to send all of the county's municipal solid waste to the county's waste-to-energy facility, and the county has a financial incentive to do so. Lee County will send municipal solid waste to the GCSL only if an emergency occurs, but even then the county will try to limit the duration and extent of the County's use of the GCSL. Objectionable Odors Objectionable odors at a landfill typically are related to the facility's operating practices (e.g., the size of the working face) and the presence of putrescible, organic materials that degrade and produce gases when they come in contact with water. In this case, the GCSL's operating practices minimize odors. The majority of the waste now received at the GCSL is ash residue, which contains little or no organic material and thus produces little or no odor. In addition, because the GCSL is a "particularly dry landfill," any putrescible waste is not likely to degrade and cause odors. There have been no violations of the DEP odor rules at the GCSL since 1991 and only two instances, in 1987 and 1991, when off-site odors were verified by DEP's inspector. WCI filed odor complaints in 1995, but the complaints were investigated by DEP and the county and found to be invalid. Petitioners presented no evidence of present or anticipated future odor problems at the GCSL. To the contrary, the DEP inspectors and other witnesses established that there are no objectionable odors at the property boundary of the GCSL. WMI's Approved Closure Plan WMI has a closure plan for the GCSL that was approved by DEP when DEP issued the existing operation permit. In the current application WMI asked DEP for authorization to close the remaining portions of Parcel 3 in the same manner that WMI used when closing the other areas at the GCSL. If WMI's request is not granted, WMI may be required to close Parcel 3 with a geomembrane cover or "cap," in accordance with DEP's new requirements for final closure plans. Although DEP's landfill engineer recommends approval of WMI's request for authorization to use an alternate cover material, no proposed agency action has been taken on that request, and DEP will provide notice and a new point of entry for affected persons when the agency decides whether to grant WMI's request. It is, therefore, inappropriate to address the merits of WMI's "alternate procedure" request in this hearing. As provided in Rule 62-701.310(3), Florida Administrative Code, the agency's decision is action subject to a separate Section 120.57, Florida Statutes, proceeding. WMI's closure plan for the GCSL has little significance in this proceeding. The closure plan is used to calculate the cost of closure, which in turn is used to determine whether WMI has the financial resources to pay the cost of closing the landfill. As part of its approved closure plan, WMI previously demonstrated that it has the financial ability to pay the cost of closing the landfill. WMI could be required to spend an additional $1,000,000 to close the GCSL if WMI's request for approval of the alternate procedure is denied by DEP, but it is undisputed that WMI has the ability to pay this additional cost for closure. WMI must submit a revised closure plan at the time when WMI is prepared to close Parcel 3. DEP then will determine again whether the closure plan for Parcel 3 is adequate and in compliance with the DEP standards in effect at the time. (See paragraphs 38-42, "Specific Conditions," appended to the Intent to Issue, WMI Exhibit 4) Leachate Generation Rate at the GCSL While evaluating WMI's request for approval of an alternate closure plan, DEP noted that the amount of leachate collected in Parcel 3 (i.e., approximately 900,000 gallons per year) is relatively low when compared to the amount of leachate generated at other landfills. DEP was concerned that the low leachate collection rate may indicate a problem in the leachate collection system, so DEP requested WMI to evaluate the leachate generation rate at the GCSL in more detail. WMI subsequently presented additional information to DEP. Leachate is defined by DEP as the liquid that has passed through or emerged from solid waste. Rule 62-701.200(50), Florida Administrative Code. Leachate is generated when rainwater falls on the landfill, sinks in, and percolates through the garbage. One of the primary factors reducing leachate at the GCSL is the use of ash as cover material. The ash, which contains lime, undergoes a reaction and "sets up like mortar." It is extremely hard, cannot be penetrated easily, and has a very low permeability. The permeability of the ash is in the same range as the permeability of the barrier layer that is used in a final cover material. The ash "sets up so well" that the surface water runoff is much greater than with a normal cover material. There is an additional, significant reason why Parcel 3 of the GCSL has a low leachate generation rate. Approximately 50 acres of Parcel 3 already have been closed with a final cover which is designed to shed rainwater and thus minimize the production of leachate. Since most or all of the remaining 30 acres of Parcel 3 have been covered with ash, virtually all of Parcel 3 is covered with low permeability materials that minimize leachate generation. Leachate in Parcel 3 also is minimized because WMI employs good operational practices to limit its generation. WMI uses a small working face and stormwater berms to reduce the size of the area where rainwater may infiltrate. WMI maintains aggressively graded slopes that quickly direct stormwater away from the working face and off of the landfill. WMI's "close-as- you-go" strategy means that the waste at the GCSL is covered before it becomes saturated with rainwater. Specific conditions in the Intent to Issue require that these practices continue. After DEP requested WMI to evaluate the leachate generation rate in Parcel 3, WMI hired a firm to clean the inside of all of the pipes in the leachate collection system in Parcel A television video camera was used to visually inspect the inside of all of the pipes. This work confirmed that "at least 99.9 per cent" of the leachate collection pipes are clean and functional. WMI promptly repaired the leachate collection pipes in two small areas where there was blockage due to a crushed riser and a valve that was left closed. It is highly unlikely that leachate is mounding up inside the landfill or overtopping the perimeter berm that surrounds Parcel 3. The leachate levels inside Parcel 3 generally are and historically have been less than two feet. The leachate levels at the GCSL do not threaten the liner's integrity. The pipes are working, and no seepage has been observed through the side slopes. WMI verified that the liner and leachate collection systems in Parcel 3 were constructed properly and in accordance with the DEP-approved design. Construction Quality Assurance reports were prepared by professional engineers when the liner systems were installed in Parcel 3. In these reports, the engineers certified that each section of the liner was installed, inspected, and tested appropriately to ensure that there are no holes in the liner. Where necessary due to failed tests, the reports reflect that repairs were made before any waste was deposited. The HELP Model In response to DEP's questions about the leachate generation rate at the GCSL, WMI's staff attempted to calculate the rate by using a computer program referred to as the HELP model. WMI initially ran the model with default input values which produced a predicted rate of 7.5 million gallons per year (MGY). WMI questioned the validity of the model results, but submitted the results to DEP because it was the best data then available. Given the discrepancy between the model results and the actual field data, WMI hired a nationally recognized consulting firm, Post, Buckley, Shuh, and Jernigan (Post Buckley), to perform a more refined analysis using the HELP model. The HELP model is used to calculate water balances at landfills. The model calculates the amount of water that will move across, into, and through landfills under different conditions. The model is a useful tool for comparing the performance of two alternate landfill designs, but it has limited value when used to predict the actual performance of an operating landfill. The model can be run with default values or with site- specific information. However, the model is designed to be conservative and overpredict the actual leachate generated. In its application of the model, Post Buckley adjusted several input parameters to reflect the actual conditions at the GCSL. Most significantly, Post Buckley adjusted the input parameters for the moisture content of the waste in the GCSL and for the U.S. Soil Conservation Service's (SCS) Curve Number. These adjustments were "reasonable and well-considered." The HELP model assumes that the solid waste in the landfill is at field capacity--i.e., saturated with rainwater. However, it is well established that the solid waste in landfills is not saturated. At the GCSL, the ash cover material and WMI's "close-as-you-go" practices would reduce the likelihood that the waste would be saturated. Indeed, Post Buckley's on-site inspections revealed that the GCSL is a "particularly dry landfill." The users' manual for the HELP model indicates that the Curve Number should be adjusted in certain cases to account for increased stormwater runoff that will occur during short duration, high intensity storms. The default value is used in areas where the rainfall occurs over a 24-hour period. In this case, Post Buckley concluded that the SCS Curve Number should be adjusted because the GCSL receives about 54 inches of rainfall annually during approximately 90 short duration, high intensity storms. Accordingly, Post Buckley adjusted the model's input parameters to increase runoff by 23 per cent of precipitation. Post Buckley's adjustment to the Curve Number and runoff value is consistent with the findings contained in a report by Benson and Pliska, which in the opinion of WMI's expert is the best study performed to-date on the calibration of the HELP model and which is similar or equivalent to the Peyton and Shroeder calibration relied on by Petitioner's expert. Post Buckley ran the HELP model with three different sets of conditions. In one run, Post Buckley adjusted the input parameter for the moisture content of the waste and calculated an leachate generation rate of 100,000 gallons per year. In the second run, Post Buckley adjusted the Curve Number and calculated a rate of 1.3 MGY. In the third run, Post Buckley adjusted both the Curve Number and the moisture content and calculated a rate of zero gallons per year. Given Post Buckley's landfill experience and its knowledge about the operational practices at the GCSL, the ash used as cover material, the climatological conditions in southwest Florida, and the limitations of the HELP model, Post Buckley concluded that 1.3 MGY is a reasonable estimate or approximation of the actual leachate generation rule for Parcel 3 of the GCSL. The leachate generation rate for the GCSL also has been evaluated by other witnesses. Mr. Joe Fluet calculated that approximately 960,000 gallons to 1,030,000 gallons of leachate are generated annually in Parcel 3. Mr. Fluet is a nationally recognized landfill expert who was selected by DEP to serve as the chairman of a technical advisory group that helped DEP develop the current DEP landfill rules. Mr. Fluet's conclusion is consistent with the leachate collection data for the GCSL, the Post Buckley analysis, the measurements of leachate in the sumps at the landfill, and his own personal observations of the landfill and WMI's operational practices. It is unlikely that leachate generation in Parcel 3 is as high as 2.0 MGY. This rate would produce about three feet of leachate on the liner. WMI's field data show that the "head" (depth) of leachate over the liner in Parcel 3 generally is less than two feet. By comparison, Post Buckley's estimated rate of 1.3 MGY would produce about 1.8 to 2.5 feet of leachate over the liner, which is more consistent with WMI's field data. Petitioners also attempted to calculate leachate generation for Parcel 3 by running the HELP model. Using default values, Petitioners calculated a rate of approximately 7 MGY. Petitioners also ran the model after adjusting several input parameters. Among other things, Petitioners decreased the slope from 20 per cent to 4 per cent, and Petitioners increased runoff by 30 per cent, as compared to the default value. With these adjustments, Petitioners calculated a rate of 4.2 MGY. The various experts' calculations with the HELP model produced leachate generation rates of 0 to 7.5 MGY. The magnitude of the range reflects the limitations of the model and underscores the need for sound professional judgment when adjusting the input parameters. In this case, the most persuasive and credible testimony was presented by Mr. Bonaparte, a recognized landfill expert who is assisting EPA with its efforts to calibrate the HELP model, and Mr. Fluet. Consistent with their testimony, the greater weight of the evidence indicates that the leachate generation rate for Parcel 3 of the GCSL is most likely to range between 960,000 gallons and 1.3 MGY. The Petitioners' calculated range of 4.2 to 7.0 MGY is not credible. Even the low end of Petitioners' range is more than twice as much (2.0 MGY) estimated by any other witness. In addition, Petitioners' entire range of calculated leachate generation rates is inconsistent with the other evidence of record, as described below. Petitioners' leachate generation calculations were prepared by Marcus Pugh, who has not visited the GCSL nor performed any site specific field work concerning the GCSL. Mr. Pugh had never used the HELP model before to predict the generation rate of an operating landfill, but rather has used it as others commonly do, to size and design facilities. Although Mr. Pugh initially criticized Post Buckley's calculation of the slopes at the GCSL, he subsequently conceded that the HELP model results obtained by Post Buckley are independent of slopes. Missing Leachate? Based on their HELP model calculations that Parcel 3 actually is generating 4.2 to 7.0 MGY of leachate and since WMI is collecting 900,000 gallons per year, Petitioners speculate that there is "unaccounted for" or "missing" leachate (i.e., 3.3 to 6.1 MGY), which must be leaking through the GCSL's liner or seeping out of the sides of the GCSL, or both. Petitioners' allegations, however, are not supported by the evidence of record, which favors a finding that the facility is simply not generating the vast amounts of leachate predicted by Petitioners. The liner and leachate collection systems under Parcel 3 were "state-of-the-art" and in full compliance with all of the applicable DEP rules at the time of their installation. These systems were installed properly, in accordance with standard quality assurance procedures, as certified by a professional engineer. Mr. Bill Krumbholz, the DEP inspector, personally witnessed the installation of portions of the liner. Mr. Fluet also was personally involved with the certification for the landfill. Even the Petitioners' witness, Mr. Pugh, conceded that he had no concerns about or disagreements with the certifications for Parcel 3. Thus, there is no reason to believe that the liner or leachate collection systems were damaged at the time when they were installed. Petitioners theorize that the liner in the GCSL may have been damaged after it was installed, but Mr. Pugh readily admits that this contention is based on "pure speculation" based on the notion that a minimum wage laborer on heavy equipment might damage the liner. Petitioners presented no direct or credible evidence to support their contention. After the completion of construction and the commencement of operations large scale breaches of a landfill liner are not a common or even occasional occurrence. As part of its standard management practices, WMI places a four-to six-foot thick "fluff" layer of select household garbage over any new landfill liner system. The fluff layer is used to protect the liner and ensure that the liner is not accidentally damaged. This WMI policy was followed when the liners were installed in Parcel 3 of the GCSL. As a result, there is no reason to believe that the liner in Parcel 3 was damaged after installation. There is no circumstantial evidence to support Petitioners' claims. Since 1976, WMI has monitored the water quality at the GCSL in accordance with a DEP-approved ground water monitoring plan, which is designed to detect any significant leakage from the landfill. No groundwater quality violations have been recorded at the GCSL. However, if one were to assume that Petitioners' theory is correct, then one also would have to assume that over the last five years approximately 16.5 to 30.5 million gallons of leachate have leaked through the liner in Parcel 3 and entered the adjacent groundwater, but somehow have evaded detection in the monitoring wells. Respondents' witness Mr. Fluet calculated that a maximum of 56,000 gallons per year of leachate might possibly leak through the liner system in Parcel 3. His calculation conservatively assumed that there may be as many as ten 0.1 cm2 holes in each acre of the liner in Parcel 3. Petitioners have offered no credible theory that would produce a leakage rate of several million gallons per year. To create a leakage rate of even one million gallons per year, there would have to be at least ten and perhaps dozens of large holes in the liner. Each of the holes would need to be 10-feet long and several inches wide. However, large holes or breaches in a liner system normally are identified and repaired during the installation and quality assurance process. There is no evidence of poor quality assurance or poor operational practices at the GCSL to support Petitioners' speculation. WMI witness, Rudolph Bonaparte, has never encountered a situation where there was evidence of the kinds of "major flaws" that would be necessary to generate the leakage rates hypothesized by Petitioners. Mr. Fluet also was unable to identify any plausible scenario that would support Petitioners' theory. Petitioners' witness, Mr. Pugh, conceded that he has never worked on a lined landfill where 4-to 7-MGY of leachate leaked through the liner. Petitioners questioned whether settlement would affect the liner or leachate collection systems in Parcel 3. Since ash is denser than MSW, the disposal of ash in the GCSL may affect the settlement of the subsurface soils to some extent, but there will be no shearing or failure of the liner due to any differential settlement. The amount of differential settlement that may occur would be extremely small. Settlement could create a 1000 gallon "puddle" of leachate in the valley fill portion of Parcel 3, or the slope in some portions of the leachate collection system may flatten, but these are relatively minor impacts. Conversely, increased settlement in the base of Parcel 3 would help improve the overall drainage of the east hill and the west hill areas. Petitioners contend that the "unaccounted for" leachate may be escaping from the GCSL through side slope seepage, but this theory is not supported by any direct or credible evidence. It was undisputed that any significant amount of side slope seepage from a landfill is readily apparent. Leachate seeps typically "look ugly and smell bad." When seeps occur, the soil is discolored, the vegetation is killed, and there is sheering, gullying, rilling, and other signs of erosion. There has been no side slope seepage from Parcel 3, as established by numerous site visits and personal observations of the DEP staff, county representatives, and other witnesses. Petitioners' witnesses have not observed any side slope seepage at the GCSL. Although Petitioners noted that there are discolored areas on Parcel 3, those are the areas where WMI recently excavated into the sides of the GCSL to complete the repairs to the leachate collection system. The leachate would have to mound up inside the landfill before there would be the amount of seepage predicted by Petitioners. This mounding would create tremendous head pressure in the cleanout pipes. However, no such pressure has been found in the cleanout pipes at the GCSL. Petitioners suggest that leachate may be seeping from the toe of Parcel 3 into the drainage ditch that leads to the stormwater retention pond. Again, the evidence does not support this hypothesis. The liner in Parcel 3 goes over the top of a berm which is built completely around the perimeter of Parcel 3. The berm and the liner rise 3 feet above the base of the leachate collection system. Leachate could not seep from the toe of Parcel 3 unless the leachate level rose above the functioning leachate collection pipes, avoided being drained away by the leachate collection system, and then flowed uphill over the berm. Even if the leachate went up and over the berm, the leachate would enter the ditch from the top of the berm, where it would be readily visible to site inspectors as side slope seepage. No such seepage has been observed at the GCSL, even when people were looking for it. Ground Water Monitoring at GCSL There are three aquifers underlying the GCSL: (a) the surficial water table aquifer; (b) a sandstone aquifer; and (c) the Hawthorne formation. Each of the aquifers is separated by a low-permeability, confining layer of varying thickness. The confining layer below the surficial water table aquifer is between 40 and 80 feet in thickness. Based on field data and reports of other scientists, including Petitioner's expert, Thomas Missimer, hydrogeologist Martin Sara derived a vertical flow rate of approximately 0.1 feet per year. At this rate, ground water would take approximately 40 to 50 years to move vertically downward through the confining layer. Petitioners contend that the GCSL is affecting the surficial water table aquifer. The surficial water table aquifer contains fresh water and is used extensively as a source of potable water in Lee County, but not in the area of the GCSL. Ground water samples collected from the surficial water table aquifer on Petitioners' property had average total dissolved solids (TDS) concentrations of approximately 500 mg/l. Similar TDS values have been reported for the surficial water table aquifer in the area surrounding the GCSL. In general, the regional groundwater flow in the vicinity of the GCSL is to the northwest. There is a northwesterly flow from WCI's property onto the GCSL that is consistent year after year and during all seasons. Extensive historical monitoring data for the site confirm that the ground- water flow under the GCSL also primarily is to the northwest, but with some likely localized flow to the west, at least during special events such as landfill dewatering in 1982. The only significant exception to this trend occurs in the area of the stormwater retention pond, where the groundwater usually flows radially outward in all directions. Groundwater monitoring began at the GCSL in 1976, when the facility opened. The groundwater monitoring system at the GCSL has complied with or exceeded the DEP requirements at all times since 1976. Currently there are seven groundwater monitoring wells, each approximately 30-feet deep, in the surficial water table aquifer at the GCSL. These wells surround the perimeter of the GCSL. At the final hearing, Lee County attempted to address concerns about the groundwater monitoring program for the GCSL by agreeing to pay for the redevelopment and installation of additional groundwater monitoring wells. Lee County and WMI stipulated that two existing groundwater monitoring wells (wells 14-S and 18-S) will be redeveloped and a new ground water monitoring well will be installed in the surficial aquifer between existing wells 20-S and 21-S. The two redeveloped wells and the new well will be sampled on a semiannual basis for chloride and the field parameters of pH, specific conductivity, field turbidity, and temperature for the life of the permit. The monitoring may be discontinued if the GCSL closes. The monitoring well network at the GCSL is adequate to monitor the type of area-wide plume that might originate from the GCSL. The evidence demonstrates that any holes in the liner in Parcel 3 are likely to be small and spread widely across the entire site. Although the plume from a single hole may be narrow and elongated, the plume from the entire landfill would be approximately 2400-feet wide. Under most if not all plausible scenarios, leachate leaking out of the liner beneath Parcel 3 will move with the regional groundwater flow toward the monitoring wells located along the western and northern perimeters of Parcel 3. Potential leakage from Parcel 3 will be pushed toward these monitoring wells by the regional groundwater flow and the radial flow from the retention pond. DEP has concluded and the evidence confirms that WMI's groundwater monitoring plan, as modified by Lee County's stipulation, is protective of the environment and satisfies all applicable DEP requirements. Under the facts of this case, it is not necessary to add any additional monitoring wells or otherwise modify the groundwater monitoring plan, except as stipulated by Lee County. It was undisputed that the leachate generated at the GCSL is and always has been "very weak" in comparison to the leachate from other landfills. The leachate contains relatively few contaminants and has low contaminant concentrations. The GCSL's leachate has few volatile or hazardous constituents. It also was undisputed that there have been no violations of DEP groundwater standards detected in any of the groundwater monitoring wells at the GCSL. There have been one- time exceedances or anomalies, but such events do not constitute a violation of the DEP standards. Chloride In the Ground Water Chloride is present in the GCSL's leachate. Over the last ten years, the average chloride concentration in the leachate has been 1021 parts per million (ppm), and the highest concentration has been 2070 ppm. The Department has no primary (i.e., health-based) groundwater quality standard for chloride. The only groundwater quality standard for chloride is a secondary standard of 250 ppm. Secondary standards are intended to address concerns about odor, taste, and aesthetics. If chloride concentrations become too high in drinking water, people simply stop drinking the water before there are any health implications, because the water is too salty. WMI evaluated Petitioners' claim that chloride leaking from Parcel 3 may affect the water quality on Petitioners' property. First, WMI performed a mass balance calculation and concluded that the maximum rate of leakage from Parcel 3 would increase the chloride concentrations beneath the landfill by only 7 to 14 ppm. WMI then used a dispersion model and determined that the maximum leakage rate would increase the chloride concentrations in the groundwater only 3.5 ppm at a distance of 100 feet from the landfill. This increase in chloride could not be distinguished from the existing background concentrations in the groundwater. WMI also analyzed the groundwater data to determine whether the GCSL is causing an increase in the chloride concentration measured in monitoring well 21-S. WMI plotted the data on trilinear diagrams, consistent with techniques that have been commonly used by hydrogeologists for many years. The trilinear diagrams clearly show that the increased levels of chloride in monitoring well 21-S are not caused by the leachate from the GCSL. The trilinear diagrams do not identify the source of the chloride found in monitoring well 21-S. However, it appears that the chloride originated from a source of "brackish" water. There are several potential sources of the chloride in well 21-S. In the past, there was an irrigation well on WCI's property that pumped water with high chloride concentrations and created a large plume of chloride-enriched groundwater on WCI's property. Historic groundwater monitoring data indicate that the chloride plume was approximately 6000-feet wide and flowing towards the GCSL. This large plume may have reached the GCSL and affected the water quality in well 21-S. There also were irrigation wells located on the site of the GCSL that may have contributed to the chloride concentrations in well 21-S. Historic water quality data indicate that these irrigation wells produced elevated chloride concentrations in the groundwater at the GCSL. Petitioners' Stormwater Data On May 12, 1997, Petitioners collected samples of the water in the stormwater retention pond at the GCSL. Petitioners also collected a sample of the water in a concrete culvert that carries stormwater runoff from Parcel 3 to the retention pond. The samples were collected during a severe rainstorm when it was "raining cats and dogs." Based on these samples, Petitioners speculate that the "unaccounted for" leachate is entering the stormwater retention pond via a perimeter drainage ditch and the concrete culvert. This speculation is not supported by the evidence. Leachate generated in the GCSL has an ammonia-nitrogen concentration in the range of 700 to 800 ppm. The stormwater collected from the culvert pipe had an ammonia-nitrogen concentration of 1.7 ppm. The disparity between these two values belies the possibility that the stormwater in the ditch contains leachate from the GCSL. Although Petitioners contend that ammonia-nitrogen in the leachate could be oxidized while flowing in the ditch, it would be virtually impossible for the oxidation of stormwater in the ditch to reduce ammonia-nitrogen levels from 700 or 800 to 1.7 ppm. WMI's extensive experience with leachate has demonstrated that it is "very difficult" to treat and reduce the ammonia-nitrogen levels in the leachate through volatization and aeration. The water collected by Petitioners in the culvert had a chloride concentration of 2900 ppm, which significantly exceeds the highest chloride level ever found in the GCSL's leachate (2070 ppm). The pH in Petitioners' sample (8.87) also was notably higher than the pH found in the landfill's leachate (e.g., 7.20 in WCI Exhibit 14). The disparity between the values found in Petitioners' sample and the values found in the landfill's leachate suggests that the Petitioners' sample is not representative of leachate from Parcel 3. Stormwater flowing over the ash residue on the top of Parcel 3 is the most probable source of the elevated chloride and high pH found in Petitioners' sample. The ash at the GCSL has elevated chloride concentrations. It also has high pH, due to the addition of lime at the waste-to-energy facility. Both WMI's witness, Mr. DeBattista, and Petitioner's witness, Dr. Missimer, saw stormwater washing over the ash and entering the stormwater conveyance system that led to the culvert where Petitioners' sample was collected while Petitioners were at the GCSL collecting samples. Petitioners noted that the water in the stormwater ditch was discolored. However, Petitioners' photograph of the site (WCI Ex. 10) reveals that the water in the ditch is the same color as the mulch (compost) that is stockpiled on Parcel 3 and used for intermediate cover. During Petitioners' site visit, stormwater was flowing over the mulch on Parcel 3 before entering the stormwater ditch. Dr. Missimer conceded that the color of the water in the ditch could be caused in part by the mulch and stormwater runoff. Dr. Missimer raised a number of other issues about the GCSL. He claimed that the sediments in the stormwater retention pond have elevated metals concentrations, but he does not contend that the metals concentrations in the sediments violate any applicable DEP standard. He also does not contend that the metals are leaving the site. Dr. Missimer noted that there was "foam" in a stormwater ditch. However, Petitioners presented no competent evidence about the source of the foam or its chemical composition. Finally, Dr. Missimer heard gas escaping from a cleanout pipe at a different location on the landfill, but there were no odors associated with it. There is no evidence to demonstrate that gas in the riser pipes is a cause for concern. In response to Petitioners' chloride data, WMI is taking steps to manage its stormwater better. WMI has placed intermediate cover over 10 acres of exposed ash, thus reducing the potential for the rainwater to come in contact with the ash and convey chloride into the stormwater management system. WMI also is determining whether it should remove a culvert that served as a conduit for the runoff from Parcel 3 to the retention pond. It was undisputed that the GCSL is an "existing installation," as that term is defined by DEP. Parcels 1 and 2 of the GCSL were unlined and were reasonably expected to release contaminants into the ground water on or before July 1, 1982. The GCSL has operated consistently with the applicable DEP statutes and rules relating to groundwater discharges in effect during the time of its operation. Since the GCSL is an existing installation, WMI is entitled to a zone of discharge that extends to WMI's property boundary. The groundwater within the zone of discharge is not required to meet the DEP water quality standards. Modifications to Conditions of Draft Permit and Summary of Findings In addition to the modification to the ground water monitoring plan described in paragraph 59 above, WMI has requested and DEP has agreed to make minor changes to the language in Specific Conditions 10, 19, 32, 38, and 45(e) of the draft permit. These changes relate respectively to gas monitoring, daily cover, acceptance of C & D debris, data to support the alternate procedure request for final cover, and the zone of discharge. These modifications are reasonable, supported by the evidence, and consistent with DEP rules. Moreover, WMI has provided reasonable assurance of compliance with all applicable DEP rules for continued operation of the GCSL. As amply demonstrated in this proceeding, highly competent professionals can disagree. Petitioners' witness Dr. Missimer, has had years of experience in studying the hydrogeology of Lee County and the area of the landfill and Gateway. His data collected during the development of Regional Impact Studies for Gateway have been relied on by DEP and others. His conclusions, however, regarding enormous amounts of leachate escaping the landfill are simply not supported by the results of years of monitoring the landfill's operations. With continued monitoring, the applicant should be permitted to continue to operate.
Recommendation Based on the foregoing, it is hereby RECOMMENDED: That the Department of Environmental Protection enter a Final Order approving Waste Management, Inc., of Florida's application for a permit renewal to continue to operate the Gulf Coast Sanitary Landfill, subject to the parties' stipulation regarding additional groundwater monitoring wells and subject to the revisions to the draft permit that are described herein. DONE AND ENTERED this 17th day of September, 1997, in Tallahassee, Leon County, Florida. MARY CLARK Administrative Law Judge Division of Administrative Hearings The DeSoto Building 1230 Apalachee Parkway Tallahassee, Florida 32399-3060 (904) 488-9675 SUNCOM 278-9675 Fax Filing (904) 921-6847 Filed with the Clerk of the Division of Administrative Hearings this 17th day of September, 1997. COPIES FURNISHED: W. Douglas Beason, Esquire Department of Environmental Protection Mail Station 35 3900 Commonwealth Boulevard Tallahassee, Florida 32399-3000 William D. Preston, Esquire Michael P. Petrovich, Esquire Post Office Box 6526 Tallahassee, Florida 32314-6526 Neale Montgomery, Esquire Pavese Garner Haverfield Dalton Harrison & Jensen Post Office Box 1507 Fort Myers, Florida 33902-1507 David S. Dee, Esquire John T. LaVia, III, Esquire Landers & Parsons, P.A. 310 West College Avenue Tallahassee, Florida 32301 David M. Owen, Esquire Lee County Assistant Attorney Post Office Box 398 Fort Myers, Florida 33902 Kathy Carter, Agency Clerk Department of Environmental Protection Mail Station 35 3900 Commonwealth Boulevard Tallahassee, Florida 32399-3000 Perry Odom, General Counsel Department of Environmental Protection Mail Station 35 3900 Commonwealth Boulevard Tallahassee, Florida 32399-3000
Findings Of Fact The Board of County Commissioners of Monroe County is responsible for maintaining a solid waste management program for the unincorporated areas of the county. The portion of the Florida Keys known as the "lower keys" between Pigeon Key on the north and Key West on the south is such an area. Prior to July 1, 1977, solid waste from this area was dumped at a site located on Middle Torch Key. Until approximately two years prior to the hearing, the Middle Torch Key dump site had been operated by private companies. The private companies apparently could not operate the site profitably under rules and regulations promulgated by the Department, and the County took over operation of the site. The site served as the solid waste dump for the lower keys until July 1, 1977. The Department had issued a temporary operating permit for the site, and open burning was permitted. The temporary permit expired on July 1, 1977. The Middle Torch Key dump site was never operated in full compliance with the Department's rules. The temporary operating permit was issued for the apparent purpose of allowing the County an opportunity to develop a system that could be operated accordance with the Department's rules. The County purchased a site on Cudjoe Key in the lower keys with the intention of utilizing it as a sanitary landfill. The instant proceeding is the culmination of the County's effort to obtain a permit to operate the Cudjoe Key site. The County has been utilizing the Cudjoe Key Site as a sanitary landfill since July 1, 1977. The Petitioners are homeowners in a residential subdivision which is located between three fourths of a mile and one mile from the proposed landfill site on Cudjoe Key. They object to operation of a sanitary landfill in such close proximity to their homes. In order to meet its obligation to maintain a solid waste disposal system, and in order to comply with DER regulations, the County needed to locate a landfill site in the area of the lower keys. The County lacks resources to truck solid waste from the lower keys to any sites in the upper keys, or on the mainland. Tie Cudjoe Key site was chosen for a sanitary landfill for two reasons. First, it was relatively isolated and had been used as a dump before. Secondly, it was for sale, and the County could afford to purchase it. The Cudjoe Key landfill site is not visible from any highway or from any residences or businesses. The site adjoins other public property, and is next to electric company property. The average height of the site is seven to eight feet above sea level. The site is located in close proximity to a borrow pit, and fill is thus obtainable at a fairly inexpensive rate. The County's plan of operation basically is to place solid waste on the site, and to cover it with six inches of landfill at the end of each working day. The site, if used in this manner, would have a useful life of approximately three years. If incineration techniques are eventually permitted, the life expectancy of the site would be increased to approximately twenty years. It does not appear that there is any ideal site for a sanitary landfill in the lower keys. There is very little dry land available that has not been previously developed. It appears that the best present alternative for solid waste disposal for the lower keys would be a joint venture with the City of Key West to desalinate salt water through incinerating activities at a site on Stock Island located just south of Key West. Neither the City of Key West, nor the unincorporated areas of the lower keys produce sufficient solid waste alone to make such a project feasible. Thus far a solution of this sort has not been politically feasible. Aside from this possibility, it appears that the proposed Cudjoe Key site is the best location for a sanitary landfill in the lower keys. The site on Middle Torch Key, which was previously operated as a dump would not comply with the Department's rules. The site is under water at high tide. In order to develop the site so that it would comply with the Department's regulation, a very large expenditure would be required. A copy of the County's completed application to the Department was received in evidence at the hearing as Department's Composite Exhibit 1. The application is complete, and contains the material required under Rule 17-7.05,, Florida Administrative Code. No competent evidence was presented at the hearing from which it could be concluded that the proposed Cudjoe Key landfill site does not comply with statutory requirements, or with the requirements set out in the Department's rules and regulations. Considerable evidence was offered from which it could be concluded that the site has not been operated in full compliance with the Department's regulations since July 1, 1977. Clearly the County has been operating the site since that date without a permit issued by the Department. It is apparent that the Department has not sought to take action against the County due to the pendency of this action. Pictures offered at the hearing, and observations made at the view of the site demonstrate that the required daily cover of solid waste has not been applied at the site. These violations could, and should if they continue, result in enforcement action being taken by the Department. The violations, and anticipated violations cannot, however, constitute grounds for denying a permit to operate a sanitary landfill site which complies with the pertinent statutes and rules and regulations.