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Home My WebLink About6013_GreenwayNorthMeckCDLF_20170808_MetalsASD_DIN28645 August 2, 2017 Ms. Jackie Drummond Compliance Hydrogeologist Division of Waste Management - Solid Waste Section North Carolina Department of Environmental Quality Asheville Regional Office 2090 US Highway 70 Swannanoa, NC 28778 Dear Jackie: Subject: North Meck C&D Landfill – Permit 60-13 Greenway Waste Solutions of North Meck, LLC Demonstration Letter on Background Metals in Groundwater Samples CEC Project 111-370.001 Per 15A NCAC 13B .0544 (b) (1) (I), Civil & Environmental Consultants, Inc. (CEC), on behalf of Greenway Waste Solutions of North Meck, LLC, is submitting this Demonstration Letter to establish that a natural variation in groundwater quality has caused contamination at the aforementioned facility. Certain metals have been detected in the groundwater that is sampled and analyzed per the approved Groundwater Monitoring Plan. These metals are regularly detected at concentrations exceeding their respective cleanup standards as published in 15A NCAC 02L .0202 (Standards), or published Interim Maximum Contaminant Levels (IMCL). This letter presents: • Statistical analysis used to determine metals of concern; • Condensed historical information on the detection of metals in groundwater at the landfill; • Information on the presence of reducing groundwater conditions and its impact on metal solubility and mobility; • Summary of published information on the background presence of selected metals in groundwater and stream sediments; and • Information on mining operations in the area of the landfill and its impact of background metals. Attachments include a site plan depicting groundwater monitoring well locations, selected field data sheets on the latest sampling event; figures on published groundwater and/or stream sediment concentration data for selected metals, and locations of gold mining operations near the Facility. Ms. Jackie Drummond - NCDEQ CEC Project 111-370.0001 Page 2 August 2, 2017 Statistical Analyses and Metals of Concern Semi-annual groundwater monitoring has been performed at the landfill for an extended period. CEC tabulated and statistically analyzed historical groundwater data for both the Closed and Infill sections of the landfill for the period 2012 thru 2017 to determine metals of concern. The criteria for selection of metals of concern are: • Any constituent must have a minimum of two detections within 2012 and 2017 above method detection limit (MDL); • The geometric mean (GM) of the data for each constituent is then determined using only values greater than MDL; • A comparison is made between the GM against the Standard or IMCL (Standard/IMCL); and • If the comparison indicates the GM is greater than the Standard/IMCL, then the constituent is a metal of concern. Using the perimeter wells only (Point of Compliance), the analyses yielded six metals of concern: 1) Chromium (10 µg/L) – GM of 10 µg/L, 27 samples above MDL; 2) Cobalt (1 µg/L) – GM of 5.1 µg/L, 29 samples above MDL; 3) Iron (300 µg/L) – GM of 1,850 µg/L, 41 samples above the MDL; 4) Manganese (50 µg/L) – GM of 166 µg/L, 83 samples above the MDL; 5) Thallium (0.2 µg/L) – GM of 6 µg/L, 2 samples above the MDL; and 6) Vanadium (0.3 µg/L) – GM of 15.7 µg/L, 57 samples above the MDL. Condensed Historical Information The groundwater-monitoring program at the North Meck C&D Landfill currently consists of 42 groundwater monitoring wells and the program has been ongoing since 1996. Semi-annual sampling and analysis is conducted per the approved Groundwater Monitoring Plan. Initial metal analyses included the RCRA 8 metals until 2011. Between 2011 and 2012, Appendix I metals were analyzed. From 2013 on, Appendix II metal analyses were added. The first available data (1999) show that barium was the first and most prevalent metal detected. Barium, cadmium, copper, mercury and selenium were observed in the historical records at levels less than their applicable current Standard. Various semi-annual reports submitted by others state that the detected values represent background concentrations in the Piedmont. Groundwater Conditions and Its Impact on Bedrock Metal Mobility Two of the metals of concern, iron and manganese, are well recognized as being part of the Piedmont bedrock/saprolite. Both of these metals are easily mobilized from the bedrock/saprolite when Ms. Jackie Drummond - NCDEQ CEC Project 111-370.0001 Page 3 August 2, 2017 reducing groundwater conditions are present. Field sampling logs generated by CEC personnel during the last two low-flow groundwater-sampling events identified a majority of the groundwater wells as having a negative Oxidation-Reduction Potential (ORP) measurement. This negative ORP indicates a reducing environment. A reducing environment allows for the converting insoluble forms of iron and manganese in the bedrock to soluble salts resulting in elevated concentrations of these metals in the groundwater. CEC has also reviewed the historical field notes from 2012 to 2016. There are notations of high turbidity in some collected samples. Similar to the solubilizing of the iron and manganese in reducing conditions, high-turbidity in Piedmont groundwater is well understood to increase the total metal concentrations compared to a low-turbidity sample. The revised groundwater sampling process of low-sampling now in practice should reduce the likelihood of high turbidity samples going forwards. Published Information on Selected Metals in Background Chromium, cobalt and vanadium are also well understood to be present in the Piedmont geology. The Energy, Land and Natural Resources Division of NCDEQ published maps(1) on the measured concentrations of these metals in stream sediments. These maps can be found in the Attachments. In these maps, significant concentrations of these three metals are observed in sediments. For example, chromium has been identified through sampling to be detected in the range of 10 to 15 milligrams per liter in stream sediments in the general area of the Facility. Likewise, for cobalt, stream sediments have been observed to have concentrations ranging from 10 to 20 milligrams per liter in the general area of the Facility. Vanadium is similar with greater than 180 milligrams per liter being detected in sediments in the general area of the Facility. CEC has also included a publication and map from the United States Geological Survey (USGS) showing the presence and history of cobalt in the central North Carolina in the Attachments. Comparing these detected stream sediment concentrations to the GM concentrations of 10, 5.1 and 15.7 µg/L of chromium, cobalt and vanadium, the presence of these metals due to naturally occurring background bedrock/saprolite is concluded. Thallium is the last metal of concern then that needs to be evaluated with respect to its presence in the background bedrock and saprolite at the Facility. Thallium has been reported in gold deposits and non-gold bearing quartz deposits by the United States Geological Society. Gold mining has been in- place in the Mecklenburg County area since the mid-19th century. Numerous gold mines have existed across the County including directly west of Facility near Holbrooks Road before Old Statesville Road (see Attachments). While specific information does not exist on the mining activities in the immediate area of the Facility, the historical location of gold mines adjacent to the Facility and the overall history of gold mining in the County and surrounding areas adds credence to its presence as a background metal. It has been detected above its method detection limit in two POC wells (MW- 8/MW-8D – Closed) once (Fall 2016) samples. It has also been detected in the background well MW-1 at the same value range (6 - 7 µg/L). The presence of the thallium in the background well; its known association with gold bearing quartz; and the presence of historical gold mining operations just west of the Facility supports the conclusion that the thallium is a naturally occurring background metal. (1) Hoffman, J.D., and Buttleman, Kim, 1994. National Geochemical Data Base: National Uranium Resource Evaluation Data for the Conterminous United States, U.S. Geological Survey Digital Data Series DDS-18- A. Ms. Jackie Drummond - NCDEQ CEC Project 111-370.0001 Page 4 August 2, 2017 Conclusion The presented data clearly supports the position that each of the six metals of concern detected in the Facility groundwater are due to their presence in the natural geology. These metals should then be removed from the Contaminants of Concern for the Facility at this time. If you have any questions or comments, please feel free to contact me at (980) 260-2130. Sincerely, CIVIL & ENVIRONMENTAL CONSULTANTS, INC. Bruce D. Reilly, P.E. Scott L. Brown, P.E. Senior Project Manager Vice President Attachments Cc: Mr. John Brown – Greenway Waste Solutions ATTACHMENTS DATE:DWG SCALE: DRAWN BY:CHECKED BY:APPROVED BY: PROJECT NO: FIGURE NO.: CHROMIUM STREAM SEDIMENT 111-370.001AS NOTEDJULY 2017 JKS DRAFT DRAFT 1 GREENWAY WASTE SOLUTIONS AT NORTH MECK, LLC NORTH MECK LANDFILL HUNTERSVILLE, NORTH CAROLINA www.cecinc.com 1900 Center Park Drive - Suite A - Charlotte, NC 28217 Ph: 980.237.0373 · Fax: 980.237.0372 DATE:DWG SCALE: DRAWN BY:CHECKED BY:APPROVED BY: PROJECT NO: FIGURE NO.: IRON IN STREAM SEDIMENT 111-370.001AS NOTEDJULY 2017 JKS DRAFT DRAFT 3 GREENWAY WASTE SOLUTIONS AT NORTH MECK, LLC NORTH MECK LANDFILL HUNTERSVILLE, NORTH CAROLINA www.cecinc.com 1900 Center Park Drive - Suite A - Charlotte, NC 28217 Ph: 980.237.0373 · Fax: 980.237.0372 DATE:DWG SCALE: DRAWN BY:CHECKED BY:APPROVED BY: PROJECT NO: FIGURE NO.: MANGANESE IN STREAM SEDIMENT 111-370.001AS NOTEDJULY 2017 JKS DRAFT DRAFT 4 GREENWAY WASTE SOLUTIONS AT NORTH MECK, LLC NORTH MECK LANDFILL HUNTERSVILLE, NORTH CAROLINA www.cecinc.com 1900 Center Park Drive - Suite A - Charlotte, NC 28217 Ph: 980.237.0373 · Fax: 980.237.0372 DATE:DWG SCALE: DRAWN BY:CHECKED BY:APPROVED BY: PROJECT NO: FIGURE NO.: VANADIUM IN STREAM SEDIMENT 111-370.001AS NOTEDJULY 2017 JKS DRAFT DRAFT 5 GREENWAY WASTE SOLUTIONS AT NORTH MECK, LLC NORTH MECK LANDFILL HUNTERSVILLE, NORTH CAROLINA www.cecinc.com 1900 Center Park Drive - Suite A - Charlotte, NC 28217 Ph: 980.237.0373 · Fax: 980.237.0372 UNITED STATES DEPARTMENT OF THE INTERIOR GEOLOGICAL SURVEY Distribution of cobalt in heavy-mineral-concentrate samples from the Charlotte 1° x 2° quadrangle, North Carolina and South Carolina by W. R. Griffitts, J. W. Whitlow, D. F. Siems, K. A. Duttweiler, and J. D. Hoffman Open-File Report 84-843-L This report is preliminary and has not been reviewed for conformity with U.S. Geological Survey editorial standards and stratigraphic nomenclature. Use of brand or manufacturer's names is for descriptive purposes only and does not constitute endorsement by the U.S. Geological Survey. 1984 This map is a product of a geochemical survey of the Charlotte 1° x 2° quadrangle, North Carolina and South Carolina, begun in 1978 that is part of a multidisciplinary study to determine the mineral potential of the area. Correlative studies are the completion of a geologic map of the quadrangle and aeromagnetic, aeroradiation, and gravity surveys (Uilson and Daniels, 1981). The Charlotte quadrangle provides a nearly complete section across the Piedmont: its northwestern corner is in the Blue Ridge, its southeastern corner is over a basin of Triassic sedimentary rocks only a few miles from the Coastal Plain. All of the quadrangle except the southeastern corner is underlain by crystalline rocks of Precambrian and Paleozoic age metamorphosed to greenschist facies in the Carolina Slate Belt and to amphibolite facies farther west. Both premetamorphic and post metamorphic intrusive rocks are present. The rocks have been weathered to permeable saprolite reaching depths of 200 feet (60 meters) in the Inner Piedmont. Because of the thorough leaching, most soils are acidic. In making the geochemical survey, we took samples of sediment within a few miles of the heads of major streams and of the tributaries of these streams, keeping the size of the drainage basin small. By doing so, we usually reduce the variety of rocks that contribute detritus to the sample, thus facilitating a correlation between sample composition and the geology of the drainage basin. At the same time, we reduce the chance that a localized cloudburst has buried the sample site with sediment from a small part of the drainage basin, thus reducing the validity of the sample as an approximate composite of the rocks of the whole basin. Nevertheless, the samples are not all geologically and geochemically equivalent. For instance, at some sites in the mountainous area in the northwestern part of the quadrangle, many clasts in the stream sediment are several yards (meters) across and collection of fine detritus suitable for a sample required a 1/2-hour search. Not far to the east, the finer sediment was abundant. In the Piedmont, the usual procedure was to sample rather coarse sediment pebble- or cobble-containing gravel and to dig deeply to the bottom of the alluvial bed or to a compact clay layer. The coarsest particles in the gravel boulders, cobbles, and coarse pebbles were excluded from the sample, which then consisted of about 10 Ibs (4 1/2 kg) of clay to granule or fine gravel sized material. The heavy minerals were extracted from this unsifted material at the sample site with a gold pan. Samples taken in the same manner on earlier projects were also used to get better coverage of the Inner Piedmont than we would have had otherwise. The quartz, feldspar, and other minerals of specific gravity below 2.89 were removed from the pan concentrate by floating them with bromoform. The heavy-mineral concentrate cleaned in that way was then separated magnetically into four fractions. The first was removed with a hand magnet, or an equivalent instrument, and not studied. The remaining concentrate was passed through a Frantz Isodynamic Separator at successive current settings of 0.5 ampere and 1 ampere with 15° side slope and 25° forward slope. The material removed from the sample at 0.5 ampere and 1 ampere will be referred to as the M-5 and Ml concentrates or fractions, respectively, and the nonmagnetic material at 1 ampere will be referred to as the NM concentrate or fraction. Most common ore minerals occur mainly in the NM fraction, making them and their contained metals easier to find and to identify. The NM fraction also 1 contains zircon, sillimanite, kyanite, spinel, apatite, sphene, and the TiC^ minerals. It is generally the most useful fraction. The Ml fraction is largely monazite in the Inner Piedmont. Because of interferences caused by cerium during spectrographic analysis and the high content of radiogenic lead in the monazite, it was necessary to remove it from the bulk concentrates to improve the quality of analyses and to permit recognition of lead, possibly derived from mineral deposits, in the NM and M-5 fraction. East of the Inner Piedmont the Ml concentrate contained very abundant epidote, clinozoisite, mixed mineral grains, including ilmenite partly converted to leucoxene, staurolite, and locally abundant spinel. The M-5 concentrate contains abundant garnet in the Inner Piedmont, dark ferromagnesian minerals in the Charlotte Belt, and ilmenite in most provinces. Mineral proportions in each magnetic fraction were estimated using a binocular microscope. Minerals of special interest were identified optically or by X-ray diffraction. The time available did not permit a thorough mineralogic study of all concentrates. Metal-rich minerals were sought in all samples that were shown by the spectrograph to contain metal in unusually high concentrations. After establishing the presence of a metal-rich mineral, the variations in metal contents among the concentrates were inferred to indicate variations in the content of metalliferous minerals. Each fraction was analyzed semiquantitatively for 31 elements using a six-step, D.C. arc, optical-emission spectrographic method (Grimes and Marranzino, 1968). The semiquantitative spectrographic values are reported as one of six steps per order of magnitude (1, 0.7, 0.5, 0.3, 0.2, 0.15, and multiples of 10 of these numbers) and the values are the approximate geometric midpoints of the concentration ranges. The precision of the method has been shown to be within one adjoining reporting interval on each side of the reported values 83 percent of the time and within two adjoining intervals on each side of the reported value 96 percent of the time (Motooka and Grimes, 1976). The lower limits of spectrographic determination for the 5 elements that are mentioned in this report are, in parts per million: cobalt, 10; gold, 20; niobium, 50; and tin, 20. All analytical data for sample material other than concentrates are taken from a report by Ferguson (1979). Such sample material is referred to as "silt" in this report. Most samples were taken by J. W. Whitlow and W. R. Griffitts. Lesser numbers were taken by D. F. Siems, A. L. Meier, and K. A. Duttweiler. The mineral analyses were made by W. R. Griffitts, K. A. Duttweiler, J. W. Whitlow, and C. L. Bigelow, with special mineral determinations by Theodore Botinelly. All spectrographic analyses were made by D. F. Siems, in part from plates prepared by K. A. Duttweiler. Steve McDanal and Christine McDougal were responsible for entering and editing the locality and spectrographic data in the RASS computer file. Many maps were subsequently plotted from this file by H. V. Alminas, L. 0. Wilch, and J. D. Hoffman. Most mineral distribution maps were plotted by K. A. Duttweiler. Cobalt is widespread in rather high concentrations in the M-5 concentrates and common but less widespread in the NM concentrates. It is 2 particularly widespread in the Carolina Slate Belt. In much of the quadrangle, cobalt is so commonly associated with gold as to indicate that both were involved in common episodes of mineralization. Cobalt is not closely associated with mafic rocks, as is indicated by the high cobalt contents of magnesium-poor M-5 concentrates (plate 1). The M-5 magnetic fraction contains the dark silicate minerals in our concentrates; most of those minerals have magnesium as a major component, so their scarcity indicates that mafic rocks, rich in ferromagnesian minerals cannot be prominent in the drainage basins. No cobalt minerals were recognized in our investigation. The abundance of manganese in the M-5 concentrates collected near Salisbury suggests that the cobalt may now be in black manganese oxide minerals, some of which are known to be cobalt accumulators. A row of clusters of cobalt-rich sample sites passes west-northwest from near the southeastern corner of the quadrangle to the vicinity of Charlotte. The mineralized area near Charlotte has long been known and exploited for gold. The area near the southeastern corner of the quadrangle, in eastern Union County, has not been exploited for any minerals. A cluster of cobalt-rich sample sites near Blacksburg also yields gold and high-zinc values. That general area contains gold-quartz veins and several kinds of iron deposits: gossans; layered quartz-hematite iron formation; and black oxides in skarn. The cobalt concentrations may be related to one or more of these types of deposit. A series of 4 cobalt-rich samples were collected along a line that trends north-northeast about 5 miles southeast of Lexington. The trend is similar to the trends of faults at the northern end of the Gold Hill fault in the vicinity, so the cobalt may have been deposited in minor, unmapped, faults related to the major ones. The Gold Hill fault itself does not yield cobalt- rich samples. An unusually large group of sites is found over and around a granite pluton south of Salisbury and extends as far west as Kannopolis. The cobalt here is associated with gold, as in most places in the quadrangle, but it also is accompanied by niobium and tin. The granite pluton is the source for the niobium and tin, but the sources of the cobalt and gold is unknown. The cobalt content of nonmagnetic concentrates calls attention to some of the same areas as that of M-5 concentrates. The area south of Salisbury is not prominent in the values in nonmagnetic concentrates; the area near Blacksburg remains prominent. The cobalt content of minus-100-mesh sediment is rather high in parts of the eastern Charlotte Belt and eastern and northern Carolina Slate Belt. Unlike the cobalt in M-5 concentrates, the high values in silt are not generally in gold areas, but are between gold areas. References Ferguson, R. B., 1979, Athens, Charlotte, Greenville, and Spartanburg NTMS 1° x 2° quadrangle areas: Supplemental data release: U.S. Department of Energy, Grand Junction, Colorado, Open-File Report GJBX 73(79), 124 p. Grimes, D. J., and Marranzino, A. P., 1968, Direct-current arc and alternating current spark emission spectrographic field methods for the semiquantitative analysis of geologic materials: U.S. Geological Survey Circular 591, 6 p. Heffner, J. D., and Ferguson, R. B., 1978, Charlotte NTMS area, North Carolina and South Carolina: Preliminary Data Release: U.S. Department of Energy, Grand Junction, Colorado, Open-File Report GJBX 40(78). Motooka, J. M., and Grimes, D. M., 1976, Analytical precision of one-sixth order semiquantitative spectrographic analysis: U.S. Geological Survey Circular 738, 25 p. Wilson, F. A., and Daniels, D. L., 1980, Simple Bouguer gravity map of the Charlotte 1° x 2° quadrangle, North Carolina and South Carolina: U.S. Geological Survey Miscellaneous Investigations Series Map I-1251-A. REFERENCE NORTH DATE:DWG SCALE: DRAWN BY:CHECKED BY:APPROVED BY: PROJECT NO: FIGURE NO.: SITE AREA TOPO SHOWING GOLD DEPOSITES 111-370.001AS NOTEDAUGUST 2017 JKS DRAFT DRAFT 6 GREENWAY WASTE SOLUTIONS AT NORTH MECK, LLC NORTH MECK LANDFILL HUNTERSVILLE, NORTH CAROLINA www.cecinc.com 1900 Center Park Drive - Suite A - Charlotte, NC 28217 Ph: 980.237.0373 · Fax: 980.237.0372 REFERENCE 8 A B 34567 12 C D E F G H 8 34567 12 A B C D E F G H DESCRIPTIONDATENOREVISION RECORDwww.cecinc.com1900 Center Park Drive - Suite A - Charlotte, NC 28217Ph: 980.237.0373 · Fax: 980.237.0372DATE:DWG SCALE:DRAWN BY:CHECKED BY:APPROVED BY:PROJECT NO:SHEET OF DRAWING NO.:SITE MAP 111-370.00011" = 200'JANUARY 2017JKSEHSEHS 1GREENWAY WASTE SOLUTIONS OFNORTH MECK, LLCNORTH MECKLENBURG LANDFILLHUNTERSVILLE, NCNORTH