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Home My WebLink AboutNC0004774_C. Andrews - Final Buck Expert Report_20160630Expert Report of Charles B. Andrews Buck Steam Station Salisbury, North Carolina S.S. PAPADOPULOS & ASSOCIATES, INC. Environmental & Water -Resource Consultants June 30, 2016 7944 Wisconsin Avenue, Bethesda, Maryland 20814-3620 9 (301) 718-8900 Expert Report of Charles B. Andrews Buck Steam Station Salisbury, North Carolina Prepared for: Duke Energy Carolinas, LLC Prepared by: Charles B. Andrews, PhD S.S. PAPADOPULOS & ASSOCIATES, INC. Environmental & Water -Resource Consultants June 30, 2016 7944 Wisconsin Avenue, Bethesda, Maryland 20814-3620 9 (301) 718-8900 Table of Contents 2'2' bV6VD06nr oe 8F b220CIVIE2' INC' Page Listof Figures................................................................................................................................. ii Listof Tables .................................................................................................................................. ii Listof Appendices.......................................................................................................................... ii Section1 Introduction................................................................................................................ 1 Section2 Background................................................................................................................ 2 Section 3 Groundwater Contamination from Ash Basins.......................................................... 4 Section 4 Remedial Actions for Groundwater........................................................................... 7 Section5 Opinions..................................................................................................................... 9 Section6 Bases for Opinions................................................................................................... 10 AvailableData.......................................................................................................... 10 Boronas a Tracer..................................................................................................... 10 Migration of Coal Ash -Related Constituents........................................................... 11 PrivateWells............................................................................................................ 11 Background Concentrations..................................................................................... 12 GroundwaterModel................................................................................................. 13 Monitored Natural Attenuation................................................................................ 13 Cap -in -Place Remedy.............................................................................................. 14 Section 7 Rebuttal of Plaintiffs' Experts................................................................................. 15 RobertParette........................................................................................................... 15 Steven Campbell and Richard Spruill...................................................................... 15 Section8 References................................................................................................................ 18 Figures Tables Appendices 1 2.2- bVbVDObnr02 9� V220CIV1E2' IMC' List of Figures Figure 1 Boron Concentrations in Ash Porewater Figure 2 Boron Concentrations in Shallow Groundwater Figure 3 Boron Concentrations in Deep Groundwater Figure 4 Boron Concentrations in Bedrock Groundwater List of Tables Table 1 Monitoring Wells with Boron Concentrations Greater than 50 ug/L and Exceedances of Groundwater Criteria for Other Constituents of Interest List of Appendices Appendix A Curriculum Vitae of Charles B. Andrews and Rate of Compensation ii REPORT 2.2- bVbVDObnr02 9� V220CIV1E2' IMC' Section 1 Introduction I was retained by Duke Energy Carolinas, LLC (Duke) to evaluate the nature, extent, and appropriate remedial actions with respect to alleged releases from ash basins at the Buck Steam Station, Salisbury, North Carolina. The work was completed to assist in litigation regarding alleged violations of state laws related to discharges to groundwater and surface water systems. My expertise includes the evaluation of the origin, distribution, fate, and transport of contaminants in the environment and selection of appropriate remedial actions. I am a Senior Principal at S.S. Papadopulos & Associates, Inc. (SSP&A) in Bethesda, Maryland. I have a Ph.D. in geology from the University of Wisconsin, and have over thirty-five years of professional experience in water -resource consulting. My qualifications, publications, trial and deposition experience are included in Appendix A. In the preparation of this report, I have reviewed and/or relied on technical reports, site documents, and records maintained by governmental agencies that describe facility characteristics, facility history, and groundwater and surface -water conditions at and in the vicinity of the facility. The list of documents I reviewed is contained in Section 8. The documents upon which I have relied are the types of documents typically used by experts to evaluate the nature, fate, extent, timing and progression of contaminants in groundwater at a site, and to select an appropriate remedial action. In addition, I visited the Site on August 13, 2014 and September 22, 2015. Finally, I have relied upon my extensive education, training and experience in the field of hydrology in formulating the opinions expressed in this report. Ash Basin Cell 1 with Buck Combined Cycle Station in Background — August 14, 2014 I 2.2- bVbVDObnr02 9� V220CIV1E2' IMC' Section 2 Background The Buck Steam Station is a former six -unit coal-fired electric generating station that began operation in 1926. The final coal-fired units were retired in April 2013. On the site is a 620 MW natural gas facility, referred to as the Buck Combined Cycle Station (BCCS), that began operation in late 2011. The site is located just south of the Yadkin River in Rowan County near Salisbury, North Carolina. Water levels in the Yadkin River are influenced by the High Rock Dam located about 13.5 miles downstream of the Buck facility. The average annual flow of the Yadkin River is reported to be 4,237 cfs and the 7 -day 10 -year low flow is reported to be 702 cfs (HDR, 2016). The river classification is Class WS -V. Coal ash from the station, consisting of fine particles captured by the pollution control equipment (fly ash) and larger particles that fall to the bottom of the boilers (bottom ash), was sluiced historically to ash basins with water from the Yadkin River. The current footprint of the ash basins is 171 acres. The ash basin system consists of three cells. There are 5.3 million tons of ash within the footprint of the ash basins, which includes the ash in the unlined ash storage area (Duke Energy, 2016). The ash basin system consist of three cells, earthen dikes, discharge structures and two canals. The ash basins are operated as a part of the station's wastewater treatment system. Currently, the ash basins receive inflows from the station yard drain sump, stormwater flows, and BCCS wastewater. Stormwater flows are estimated to average about 0.36 million gallons per day, and flows from the BCCS average about 1.3 million gallons per day, with most of the flow from the cooling towers and condenser system. During the later years of operation of the coal-fired units, flows to the ash basins averaged 4.4 million gallons per day. The original ash basin, which corresponds to the current Cells 2 and 3, was constructed in 1957 by building a dam along the Yadkin River. This original dam had a crest of 2 2.2- bVbVDObnr02 9� V220CIV1E2' JWC' �S 680 feet MSL, approximately 60 feet above the level of the Yadkin River. The crest of the dam was raised 10 feet in 1977 when the ash basin was subdivided into the current Cells 2 and 3. Cell 1 was constructed in 1982. The combined footprints of Cells 2 and 3 are approximately 81 acres and the footprint of Cell 1 is 90 acres. In June 2015, the water levels in the ponds in Cells 1, 2 and 3 were 701 feet MSL, 682 feet MSL and 673 feet MSL, respectively (HDR, 2015a, page 12). An unlined ash storage area is located adjacent to the east side of Cell 1. The area was constructed in 2009 by removing ash from Cell 1 to increase storage for sluiced ash. The footprint of the ash storage area is approximately 14 acres. An extensive evaluation of groundwater and surface water conditions has been conducted over the past two years. These evaluations were conducted to comply with the requirements of the North Carolina Coal Ash Management Act of 2014 requiring groundwater monitoring, assessment, and remedial activities, if necessary. The results of these evaluations are described in three reports that were prepared as of June 2016; "Comprehensive Site Assessment Report — Buck Steam Station Ash Basin" (HDR, August, 2015a), "Corrective Action Plan Part 1 — Buck Stream Station Site" (HDR, November 2015b), and "Corrective Action Plan Part 2 — Buck Steam Station Site" (HDR, February, 2016). These reports are referred to as the CSA report, the CAPI report, and the CAP2 report, respectively. The data and evaluations contained in these reports have been used to define a volume of groundwater that contains ash -related constituents. The groundwater conceptual model developed in the CAP2 report describes the groundwater system as an unconfined aquifer system consistent with the LeGrand slope -aquifer system model (LeGrand, 2004). The groundwater system is divided into three layers referred to as the shallow, deep (transition), and bedrock zones. The shallow zone consists of alluvium and/or saprolite. The deep zone consists of the weathered and/or fractured bedrock zone from auger refusal to the top of intact bedrock. The bedrock is primarily volcanic tuffs and flows with minor intrusives that have been metamorphosed to upper amphibolite grade of metamorphism (CSA, page 10). The alluvium is reported to be up to 32 feet thick, the saprolite and weathered rock is reported to be between 24 and 117 feet thick, and the weathered/fractured bedrock zone is reported to range up to 16 feet thick (CAP 1, page 38). Groundwater flow is generally from south to north beneath the ash basins toward the Yadkin River. A topographic divide is located approximately along Leonard Road to the south of the ash basins and the groundwater divide is likely located in proximity to the topographic divide. 3 1.1 Section 3 2.2- bVbVDObnr02 9� V220CIV1E2' 1WC' Groundwater Contamination from Ash Basins Porewater within the ash basins contains a number of dissolved inorganic constituents at concentrations that are greater than those typically found in groundwater in the vicinity of the Buck site. As a result, porewater percolating into groundwater has the potential to influence the water quality characteristics of the underlying and adjacent groundwater. In the CAP2, sixteen constituents of interest were identified for groundwater: antimony (Sb), arsenic (As), barium (Ba), boron (B), chromium (Cr), hexavalent chromium (CrVI), cobalt (Co), iron (Fe), manganese (Mn), nickel (Ni), selenium (Se), pH, sulfate (SO4), thallium (Tl) total dissolved solids (TDS), and vanadium (V). These constituents of interest were identified based on exceedances of North Carolina's 2L Groundwater Standards (2L Standards) and exceedances of North Carolina's Interim Maximum Allowable Concentrations (IMAC).' The water quality of the porewater in the ash basins has been characterized by porewater samples collected from 10 monitoring wells installed within the ash basins and screened in the ash. The table below lists the median, 75 -percentile and 90 -percentile concentrations for the porewater, based on the samples collected from the monitoring wells screened in the ash for all constituents of interest except for pH, iron and manganese. These three potential constituents of concern are discussed in the expert report of Dr. Remy Hennet. The data on the table below provide information on the dissolved concentrations in the porewater that can potentially migrate to groundwater. Only two of the constituents of interest exceed the 2L Standard based on the median and 75 -percentile concentrations; arsenic and boron. The measured concentrations of boron in the porewater are shown in map view on Figure 1. Concentrations of Potential Constituents of Interest in Ash Porewater at Buck 2L Standard IMAC Median Concentration 75 -Percentile Concentration 90 -Percentile Concentration Antimony (u /L) 1 1.7 8.9 15 Arsenic (u L) 10 340 470 927 Barium (m /L) 0.7 0.30 0.43 0.57 Boron (ug/L 700 1,500 2,375 4,448 Chromium (ug/L) 10 1.5 4.2 8.4 Chromium VI (u ) 0.01 0.02 0.4 Cobalt (u /L) 1 1.7 4.2 9.5 Nickel (u /L) 100 4.9 11 19 Selenium (ug/1- 20 0.21 0.52 0.93 Sulfate (mg/L) 250 78 128 198 Thallium (u L) 0.2 0.1 0.23 0.61 TDS (mg/L 500 277 425 741 ' The 2L groundwater quality standards are established under 15A NCAC 02L.0202. Interim Maximum Allowable Concentrations (IMAC) are established under 15A NCAC 02L.0202. The value for vanadium discussed in this report is based on a memorandum from Mollie Young, Director of Legislative Affairs North Carolina Department of Environmental Quality to the Environmental Review Commission and the Joint Legislative Oversight Committee on Health and Human Services, dated April 1, 2016. 2.2- bVbVDObnrO2 9� V22OCIV1E2' JWC' Vanadium (ug/L 20 9.8 1 40 166 The long-term leachability of the constituents of interest from the ash within the ash basin was evaluated by conducting leaching tests, using EPA Method 1312 (Synthetic Leaching Test Procedure — SPLP), on 14 ash samples collected from borings advanced within the ash basins. This test method provides an estimate of leaching potential for the conditions utilized in the test procedure. The median, 75 -percentile and maximum concentrations reported in the leaching liquid from these tests are listed on table below. Arsenic is the only constituent of interest that exceeds the 2L Standard based on median and 75 -percentile concentration, and chromium exceeds based on 75 -percentile concentration. Antimony, cobalt and vanadium exceed their respective Interim Maximum Allowable Concentration (IMAC) based on median and/or 75 -percentile concentrations. Concentrations of Constituents of Interest in Ash Leachate from Method 1312 2L Standard IMAC Median Concentration 75 -Percentile Concentration Maximum Concentration Antimony (u /L) 1 4.4 6.0 8.5 Arsenic (u ) 10 20 122 205 Barium m /L) 0.7 0.23 0.35 0.49 Boron (ug/L) 700 108 118 345 Chromium (u /L) 10 2.2 13 43 Cobalt (u /L) 1 0.5 2.0 30 Nickel u /L) 1.2 3.7 19 Selenium (ug/L 20 1.1 2.9 27.4 Sulfate (mg/L) 250 14.5 24.3 32.6 Thalium (ug/L) 0.2 0.02 0.09 0.5 Vanadium (u /L) 20 45 168 345 Boron and sulfate are the most mobile of the constituents of interest listed on the tables above, as these compounds are generally non-reactive in groundwater and migrate at the rate of groundwater. These constituents are widely recognized as leading indicators of contamination from coal ash.2 Boron concentrations in the ash porewater are elevated much more above background levels than is sulfate at the Buck facility. Thus, boron is the better tracer for extent of groundwater contamination related to the ash basins. A series of maps were prepared to illustrate the magnitude and spatial extent of boron in groundwater in the vicinity of the ash basins. Boron concentrations in shallow groundwater are displayed on Figure 2, boron concentrations in deep groundwater are displayed on Figure 3, and boron concentrations in bedrock are displayed on Figure 4. The boron concentration data displayed on these figures are based on 1) the maximum of reported concentrations for monitoring wells and the water supply well at the Buck facility as reported in the CAP2 report, and 2) the results of the sampling of the private bedrock wells as reported in Appendix B of the CSA report. The typical detection limit for boron used in the analyses conducted for the CSA was 50 ug/l; as a result, only 2 U.S. EPA's Final Rule regarding Disposal of Coal Combustion Residuals from Electric Utilities, 40 CFR Parts 257 and 261, specifies that detection monitoring constituents are boron, calcium, fluoride, pH, sulfate and total dissolved solids as these parameters are known to be leading indicators of releases of contaminants associated with coal combustion residues. 5 2.2- bVbVDObnr02 9� V220CIV1E2' JWC' �S reported values of greater than 50 ug/L are posted on Figures 2 to 4. The analytical detection limit for samples from some private wells were greater than 50 ug/L; these wells are not displayed on Figure 4. The highest boron concentrations in groundwater are located beneath the ash basins and adjacent to the river. The pattern of elevated boron concentrations are consistent with infiltration of water from the ash basins to the groundwater and migration of groundwater with elevated concentrations of boron toward and into the river. Seeps have been observed along the small tributary to the Yadkin River to the northeast of Cell 3, along the toe of the main dike for Cells 2 and 3 and along the small tributary to the Yadkin River to the northwest of Cell 1. The elevated boron concentrations measured in some of these seeps is consistent with migration from the ash basins toward the river. The extent to which constituents of concern are retarded (attenuated) in groundwater relative to boron is illustrated by reported concentrations of all of the other potential constituents of interest as less than the 2L standard or IMAC or detected at relatively low concentrations (relative to concentrations in the ash porewater) at many of the monitoring wells with reported boron concentrations greater than 50 ug/L. A tabulation of all monitoring wells with dissolved boron concentrations greater than 50 ug/L and the concentrations of other constituents of interest, if greater than groundwater criteria, are listed on Table 1. Over thirty percent of monitoring wells with boron concentrations greater than 50 ug/L do not have exceedances of groundwater criteria for the other constituents of interest3. Arsenic, which is reported in ash porewater at concentrations well above the 2L standard, was only reported in two monitoring wells, excluding those completed in the ash, at concentrations above the 2L standard (AB-5BRU and GMA-18D). The dissolved arsenic concentrations in these wells were reported as 26.7J+ ug/L and 15.2 ug/L, respectively. The total arsenic concentration in AB-5BRU, though, was only 7.1 ug/L. The dissolved concentration, rather than the total concentrations, reflects the arsenic with the potential to migrate with groundwater. Both of these wells are located between Cell 3 and the river. 3 This includes monitoring wells A13-11), A13-813RU, A13-913, AS -113, MW -11D, MW -1D, MW -3D, MW -4D, MW - 5D, and MW -5S. In addition, monitoring wells GWA-413, MW -3D, and MW -4S only have exceedances of 2L Standards for manganese. The maximum reported manganese concentrations in these three wells is 70 ug/L. IN 2.2- bVbVDObnr02 9� V220CIV1E2' JWC' Section 4 Remedial Actions for Groundwater The North Carolina Coal Ash Management Act of 2014 requires that a corrective action for the restoration of groundwater quality shall be implemented at the Buck facility. This corrective action is required to be sufficient to protect public health, safety, and welfare; the environment; and natural resources; and to be consistent with 15A NCAC 02L. The CAP2 report states that Duke is planning to utilize cap -in-place as a source control measure at the Buck ash basins by constructing an engineered cap system over the ash basins, in conjunction with monitored natural attenuation (MNA), as the corrective action for groundwater. In addition, the CAP2 report states that if monitoring determines that MNA is insufficient for restoration of groundwater quality, that additional remedial alternatives will be considered and implemented, if warranted. As described in the CAP2 report, with a cap -in-place remedy, infiltration (recharge) of water from the ash to the underlying groundwater will be significantly reduced. This reduced infiltration will lower water levels within the ash, but will not completely dewater the ash. Some groundwater will continue to flow through the remaining saturated ash toward the river into the future, but the amount of flow through the ash will be significantly less than under current conditions. As a result, constituents of interest from the ash basin will continue to migrate with the groundwater toward and diffusely discharge into the river. The analyses that were conducted for the CAP2 report indicate that this continuing discharge to the river is protective of public health, safety and welfare, the environment, and natural resources, and is consistent with 15A NCAC 02L. In addition, as monitoring is an integral component of the remedy, data will be collected on an ongoing basis to verify that the remedy remains protective. Experts for the Plaintiffs in this litigation opine that the appropriate corrective action for groundwater at the Buck facility is removal of all of the ash within the ash basins as well as additional remedial components. The expert report of Campbell and Spruill states (Campbell and Spruill, 2016b, page 36): "We are more convinced than ever that Duke should do for the Buck site what is being [sic] doing for seven of the other coal ash sites in North Carolina and all coal ash sites in South Carolina; promptly excavate and transfer the coal ash to an engineered, encapsulating, water free, properly maintained, and regularly -monitored repository. We also assert that coal ash derived contamination impacting groundwater and surface water will require additional assessment after the coal ash is removed, and that the contamination will require remediation using methods protective of human health and the environment, in particular the potable groundwater resources used by many hundreds of people living near the Buck site. " In addition, another Plaintiffs' expert opines that: "Monitored Natural Attenuation is not an appropriate remedy for constituents of interest (COIs) at the Buck site " (Parette, 2016, page 10). 7 2.2- bVbVDObnr02 9� V220CIV1E2' IMC' �S J The experts for the Plaintiffs opine that a source removal corrective action is preferred over the cap -in-place remedy for two main reasons: 1) they believe there is a significant risk of migration of ash basin related constituents to nearby private wells with a cap -in-place remedy and 2) due to saturated ash remaining in place ash basin related constituents will continue to migrate to the river. The experts provide no quantification of the risk to nearby wells with a cap -in-place remedy. Rather it is a generic conclusion based on the complexities of groundwater flow in fractured bedrock aquifers. As discussed later in this report, my opinion is that the risk to nearby wells is insignificant based on available information, and can be mitigated with groundwater monitoring. An evaluation of corrective action plans for groundwater, as specified in 15A NCAC 02L, shall consider the following; • The extent of any violations; • The extent of any threat to human health or safety; • The extent of damage or potential adverse impact to the environment; • Technology available to accomplish restoration; • The potential for degradation of contaminants in the environment; • The time and costs estimated to achieve groundwater quality restoration; and • The public and economic benefits to be derived from groundwater quality restoration. The Plaintiffs' expert reports contain limited or no discussion of most of these factors, even though they opine on the appropriate corrective action. N. 2.2- bVbVDObnr02 9� V220CIV1E2' IMC' Section 5 Opinions Based on the data and information that I have reviewed and my experience and education, I have formulated the following opinions: • The data on ash and groundwater characteristics collected in the investigations conducted at the Buck facility provide an adequate and appropriate foundation for selecting an appropriate remedy for the alleged violations (releases from the ash basins). • Boron is an excellent tracer of groundwater migration from the ash basins. As a result, it is not probable that groundwater with boron concentrations at background levels has been affected by ash -related constituents that have migrated from the ash basins. • Coal ash -related constituents have been infiltrating into and migrating with groundwater since the first ash basin was constructed and used in 1957. Boron has migrated in groundwater from the ash basins to groundwater discharge areas along and beneath the Yadkin River. The extent of groundwater contamination resulting from migration of coal ash -related constituents is defined by elevated boron concentrations in groundwater, and the extent is limited. Site data indicate that migration of ash -related constituents, other than boron and sulfate, in groundwater are significantly attenuated relative to boron. • Groundwater sample results from private wells in the vicinity of the ash basins are an excellent foundation for evaluating potential past migration, and potential future migration, of groundwater from the ash basins toward these wells. • Constituents in coal ash occur naturally. The background concentration of a specific constituent is not a single value but is rather a range that represents, in part, the characteristics of the source material and potential anthropogenic factors. • The groundwater model developed for the site is a useful tool for integrating the available groundwater data, interpreting groundwater flow and water quality conditions, and evaluating the relative performance of alternative corrective actions for groundwater. • Dispersion and dilution are natural attenuation processes to be considered in MNA evaluations. • A cap -in-place remedy, with monitoring, can be protective of water -quality in nearby private and public wells and water -quality in the Yadkin River. Similar remedies have been successfully utilized at numerous sites in the United States. • Consideration of the factors specified in 15A NCA 02L for evaluation of corrective action does not support excavation and removal of the contents of the ash basins at Buck. I hold these opinions with a reasonable degree of scientific certainty. I reserve the right to modify and supplement these opinions should additional information become available. X 2.2- bVbVDObnr02 9� V220CIV1E2' JWC' Section 6 Bases for Opinions The foundation for each of my opinions is described below. Available Data Extensive data on groundwater and subsurface conditions at the Buck facility have been collected as part of the investigations conducted at the facility. Groundwater quality data are available from 101 monitoring wells, over 75 private wells in the vicinity of the site, and seeps at the site. In addition, ash and soil mineralogy and chemistry data are available from a large number of samples collected during the advancement of borings; leaching data are available for ash samples; and laboratory sorption data are available for selected subsurface samples. Data on the physical characteristics of the subsurface are available from boring logs and from slug tests conducted at each of the monitoring wells, and water -level monitoring data. These data are sufficient for defining the extent of groundwater contamination and potential migration pathways for purposes of selecting an appropriate groundwater corrective action. This does not imply that additional data are not, and will not, be needed to design an appropriate remedy. Boron as a Tracer Boron is an excellent tracer for two primary reasons. First, dissolved boron is present in the ash porewater at concentrations significantly elevated above background levels. Boron concentrations in ash porewater range up to 8,800 ug/L (which is more than 175 times greater than the background boron concentration). Second, dissolved boron, which occurs typically as boric acid, has minimal interaction with the solid phases in the subsurface. An Eh -pH diagram for boron, illustrating that boric acid (H31303) is the stable form of dissolved boron, at conditions encountered in the vicinity of the ash basins, is shown to the right (Brookins, 1988). Migration of the constituents of interest away from the ash basins occurs primarily as dissolved transport of the -° 0 2 Q 6 PH $ ao 12 14 constituents of interest with migrating groundwater. Boron E"H [] Wam for B -0-H system dissolved in groundwater as boric acid is relatively non-reactive in the subsurface as it is not sorbed onto mineral surfaces and is stable under a range of Eh and pH conditions. Many of the dissolved constituents of interest, unlike boron, sorb to mineral surfaces and/or complex with metal oxides. This results in an apparent rate of migration of these constituent that is slower than the rate of groundwater flow (and the rate of boron migration). Since boron migrates as fast as or faster than other constituents of interest, and since boron is still present in porewater in the ash basins, boron is a reliable indicator of any ash -related contamination. A corollary to this last sentence is that absent elevated boron concentrations in a groundwater sample, it is unlikely that the groundwater sample has been contaminated by the migration of ash related 10 2.2- bVbVDObnr02 9� V220CIV1E2' IMC' constituents from the ash basins. A possible exception may occur in very acidic groundwater where cobalt may leach from the ash and native materials and migrate at approximately the speed of groundwater (USEPA, 2015b). Migration of Coal Ash -Related Constituents Since dissolved boron migrates at approximately the speed of groundwater, the percolation of water from the ash basins since 1957 into the underlying groundwater can be considered as a nearly 60 -year long tracer test. The results of this nearly 60 -year long tracer test are depicted on Figures 2, 3, and 4 which present the measured boron concentration in groundwater in 2015 in the shallow, deep and bedrock groundwater zones. The extent of groundwater impacted by migration of ash -related constituents is defined by measured boron concentrations in monitoring wells that are greater than the normal detection limit of 50 ug/L. An examination of the spatial distribution of monitoring wells on Figures 2, 3 and 4 with boron concentrations greater than 50 ug/L indicate that the extent of impacted groundwater is limited. The distribution of boron in groundwater indicates that boron has migrated from the ash basins to groundwater discharge areas along and beneath the Yadkin River. Under current conditions, some groundwater with elevated concentrations of boron discharges to seeps along the Yadkin River and tributaries. Groundwater with elevated concentrations of boron also discharges diffusely to the wetlands adjacent to the river and to the beds of the river and its tributaries. Groundwater with elevated concentrations of boron does not migrate under the river, all groundwater containing elevated concentrations of boron is flowing toward the north and discharges into the river and into low lying areas to the south of the river. The monitoring data from the Buck facility clearly illustrates that migration of most of the identified constituents of interest in groundwater is retarded relative to the rate of migration of boron in groundwater. A tabulation of all monitoring wells with dissolved boron concentrations greater than 50 ug/L and the concentrations of other constituents of interest, if greater than groundwater criteria, are listed on Table 1. Over thirty percent of monitoring wells with boron concentrations greater than 50 ug/L do not have exceedances of groundwater criteria for the other constituents of interest. This demonstrates that the migration in groundwater of other constituents of interest is attenuated relative to the migration of boron. Private Wells Seventy-seven private wells within one-half mile of the Buck facility were sampled between February and July 2015. Typically, private wells in the area are open hole completions in the bedrock, with well depths ranging to several hundred feet (CSA, Table 4-1). The water quality results from these wells provide an excellent database of groundwater quality in the bedrock in the vicinity of the Buck facility. Boron was detected only in two and the 77 wells sampled, at concentrations of 5.8 ug/L and 7.7 ug/L, respectively (which are in range of background boron concentrations).' Concentrations of all other potential ash basin -related constituents also were within the range of background concentrations. These results are consistent with groundwater flow 4 The detection limit for 12 of the water samples from private wells were greater than 50 ug/L. 11 2.2- bVbVDObnr02 9� V220CIV1E2' IMC' �S from beneath the ash basins towards the Yadkin River or its tributaries, and not toward the upgradient residential wells. These flow patterns are also consistent with the observation that the highest nitrate concentrations in groundwater occur in the monitoring wells located along the southern and southeastern perimeter of the ash basins, consistent with nitrate sources in the residential areas. The use of water -quality data from private wells to define the extent of contamination is often incorrectly criticized because such wells are not constructed in the same manner as monitoring wells. For example, the private wells frequently have long open intervals in the bedrock, and for many wells the length of the open interval is unknown. In the vicinity of the Buck facility, where groundwater flow in the bedrock is primarily through fractures, private wells intersect the fractures through which the groundwater flows. In fact, the depth of private wells is variable because fracture density is variable. Wells are typically drilled until sufficient fractures have been intersected to supply sufficient water to the well. Since the wells intersect the water yielding fractures, if migration of constituents of interest has occurred in the fractures, the water produced from these wells for sampling will contain the constituents of interest. Drs. Campbell and Spruill have opined that contaminated groundwater migrates rapidly in the fractured bedrock aquifer in response to fracture orientation, fracture connectivity, head distribution and hydraulic influences from pumping by area water -supply wells (2016a, pages 10-11). With rapid migration in the fractures, it is expected that if migration of ash related constituents from the ash basins to the private wells is occurring, that the migration of the more mobile of these constituents to the private wells would have already occurred given the time since initial use of the ash basins. Background Concentrations A complexity in defining the extent of groundwater affected by migration of ash -related constituents occurs because all of the identified constituents of interest in groundwater occur naturally in soil and groundwater in the vicinity of the Buck facility, and because the naturally - occurring concentrations of several of the constituents of interest are greater than either the 2L Standards or the IMACs. The naturally -occurring concentrations of a specific constituent of concern is a function of many factors including, but not limited to, the nature of geologic materials, redox conditions in groundwater, groundwater age, land use, and anthropogenic factors.6 As a result of the many factors that influence naturally -occurring concentrations of the constituents of interest in groundwater, naturally -occurring concentrations (also known as background concentrations) represent a range of concentrations in the vicinity of the Buck facility and vary among the aquifer zones and with spatial location. The range of background concentrations is well illustrated from the results of the private well sampling for vanadium and total dissolved solids, as in my opinion, the water -quality results from these wells represent background groundwater quality. Water -sample results are available 5 In the report, "naturally -occurring concentration" refers to the concentration that would occur in groundwater if the ash basins had not been constructed and operated. 6 Refer to papers by Oze and Dendorf (2007) and Wright and Belitz (20 10) for a discussion of the influence of nature of geologic materials on hexavalent chromium and vanadium, respectively, in groundwater. 12 2.2- bVbVDObnrO2 9� V22OCIV1E2' JWC' �S for 77 wells within one-half mile of the Buck facility, and an additional nine wells that are located much further from the facility. The results from the sampling of the wells within one-half mile of the site indicate that vanadium concentrations in bedrock range from <1 ug/L to 25.6 ug/L with a median value of 3.5 ug/L and a 75 -percentile value of 6.1 ug/L. The results from the sampling indicate that total dissolved solids concentrations in bedrock range from <25 mg/L to 1,130 mg/L with a median value of 89 mg/L and a 75 -percentile value of 113 mg/L. These results provide information on the wide range of naturally -occurring vanadium and total dissolved solids concentrations in bedrock groundwater in the vicinity of the Buck facility. As a result of this large range in naturally -occurring vanadium and total dissolved solids concentrations, there can be ambiguity regarding the source of vanadium and total dissolved solids in a given groundwater sample. This ambiguity can be resolved by using multiple lines of evidence including an evaluation of the presence or absence of a tracer of ash -related migration (such as boron) at concentrations above background levels, and by evaluating the processes responsible for migration of ash related constituents in groundwater. Groundwater Model A groundwater model of the Buck facility and vicinity is described in the CAP and CAP2 reports. This model was prepared primarily to integrate available information on groundwater conditions at the facility, such that the future distribution of ash -related constituents in groundwater and the mass flux of ash -related constituents to surface water could be compared in a relative manner under three future scenarios: existing conditions, cap -in-place, and source removal. The model that was developed provides a framework for making this type of relative evaluation. The model that was developed, as are all models, is a simplified representation of a complex groundwater system. As a representation of a system, rather than an exact replica, the goal of the model is not to incorporate all details of the subsurface environment, but rather only those details and processes relevant to the objectives of the modeling analyses (Anderson and others, 2015). The appropriate details and processes have been represented in the model. The use of the model, as described in the CAP 1 and CAP2 reports, has provided insight on migration of constituents of interest in groundwater. As modeling is an iterative process, these insights and additional information are being incorporated into the model to make it a better tool for evaluating future scenarios. Appropriately, the model is not a static tool but rather a dynamic one that is being used to evaluate future scenarios. The model, though, is only a tool, and it is only one component of the evaluations being conducted to choose an appropriate corrective action for groundwater. Monitored Natural Attenuation Monitored Natural Attenuation (MNA), as defined by the U.S. EPA, includes: "....biodegradation; dispersion; dilution; sorption; volatilization; radioactive decay; and chemical or biological stabilization, transformation, or destruction of contaminants " (USEPA, 1999, page 3; USEPA 2015a, page 7). The primary natural attenuation processes for boron at the Buck facility are dilution and dispersion. These processes result in a reduction in boron concentration downgradient of the ash basin, and thus a reduction in potential exposure levels. For 13 2.2- bVbVDObnr02 9� V220CIV1E2' IMC' constituents other than boron and sulfate, attenuation mechanisms include geochemical processes and surface interactions, in addition to dilution and dispersion. Cap -in -Place Remedy A cap -in-place remedy will reduce to negligible levels the amount of water that percolated from the ground surface vertically through the ash residing in the ash basins to the groundwater system. Based on the recharge rate for the ash basins specified in the groundwater model described in the CAP2 report, capping the ash basins will reduce groundwater recharge by approximately 100 million gallons per year. This recharge reduction will result in a nearly identical reduction of the diffuse groundwater discharge from beneath the Buck facility to the Yadkin River. This reduction in groundwater discharge to the Yadkin River will, by itself, result in a reduction in the mass flux of ash -related constituents to the Yadkin River from current levels. The water table beneath the ash basins will decline from current levels following capping due to the reduction in groundwater recharge. The decline in the water table will not be sufficient to dewater the ash within the basins, as the ash fills tributary valleys that prior to construction of the basins were groundwater discharge areas. As a result, groundwater will continue to migrate through the remaining saturated ash and discharge in a diffuse manner to the Yadkin River. The decline in the water -table beneath the ash basins, and adjacent areas, will result in the groundwater divide on the south moving northward. This will result in groundwater levels that demonstrate more clearly than current groundwater levels, the northward components of groundwater now beneath the ash basins. The cessation of vertical water movement through the ash following capping is not anticipated to lead to significant changes in oxidation-reduction conditions in groundwater within and beneath the ash basins. Ash porewater, based on data collected for the CSA, currently is reducing at most locations, with a median Eh reading of -37.5 and ranging to as low as -205. Similar Eh conditions are expected to persist in the ash porewater following capping. As a result, the sorption characteristics of the ash and underlying geologic materials are not anticipated to change following capping. Water quality standards for ash -related constituents are not currently exceeded in the Yadkin River based on analyses conducted for the CAP2 report. With a cap -in-place remedy, the mass flux to the river of ash -related constituents will be reduced, and as a result water quality standards in the river will not be exceeded in the future. A cap -in-place remedy will be protective of public health, safety and welfare, the environment, and natural resources. With a cap -in-place remedy, groundwater flow in the vicinity of the ash basins will be toward the river, and not toward areas with private wells, and water - quality standards in the river will not be exceeded. 14 2.2- bVbVDObnr02 9� V220CIV1E2' JWC' Section 7 Rebuttal of Plaintiffs' Experts Robert Parette Dr. Parette in his expert report states his major opinion as follows: "Monitored natural attenuation is not an appropriate remedy for constituents of interest (COIs) at the Buck site. " (Parette, 2016, page 8). Dr. Parette's opinion is inconsistent with the extensive groundwater quality data collected at the Buck facility that demonstrate that constituents of interest are naturally attenuated with distance downgradient of the ash basin, as described in Section 6. For constituents other than boron and sulfate, this attenuation is the result of geochemical processes and surface interactions, in addition to dilution and dispersion. Dr. Parette incorrectly assumes that physical attenuation processes, such as dilution and dispersion, are not appropriate for consideration in a natural attenuation remedy as described in Section 6. Dr. Parette opines that conditions for monitored natural attenuation (MMA) will be less favorable following capping as he believes capping will lead to more anoxic conditions. As explained in Section 6, groundwater conditions are not likely to become more anoxic following capping. The data show, however, significant retardation of antimony, chromium and cobalt relative to boron under current conditions. These site-specific data clearly demonstrate that natural attenuation processes are effective in reducing concentrations of constituents of interest, and will be favorable for natural attenuation in the future. Steven Campbell and Richard Spruill Drs. Campbell and Spruill prepared an initial expert report and an addendum to the initial expert report (2016a, 2016b). The primary opinions of Drs. Campbell and Spruill are stated on page 8 of the Addendum (2016b): • "...the most protective remediation option for coal ash at the Buck property is complete excavation," and • "...coal ash -derived contamination impacting groundwater and surface water will require additional assessment after coal ash is removed, and that the contamination will require remediation using methods protective of human health and the environment, in particular the potable groundwater resources used by many hundreds of people living near the Buck Site." The foundation for their rejection of a cap -in-place remedy is that with a cap -in-place remedy "...water will continue to saturate considerable volumes of coal ash, resulting in the delivery of ash -derived contaminants indefinitely to the groundwater system and the Yadkin River" (Addendum, page 2), and "... exceedances [of groundwater standards] will persist for decades to centuries under the current site conditions and under Duke's recommendation to cap the coal ash, and that 15 2.2- bVbVDObnr02 9� V220CIV1E2' IMC' ash -contaminated groundwater will continue to discharge to the Yadkin River for decades to centuries (Addendum pages 1-2), and "We conclude that Duke's own data and map indicate that groundwater has potential to migrate toward the southeast and east, groundwater in the southeastern portions of the Buckproperty will flow toward area residential properties and potable water supply wells, and this indication exists even though the influence of dozens of pump water -supply wells is not revealed by incorporating water -level data south of the Buck property. " (Addendum page 10). It is important to note the Drs. Campbell and Spruill did not evaluate, or opine, on the impact of a continuing migration of the ash -derived constituents to the Yadkin River. As noted in Section 6 above, the existing groundwater discharge does not result in an exceedance of surface - quality standards in the river, and will not result in an exceedance in the future. Drs. Campbell and Spruill note that: "...most residential water -supply wells in the area have been pumping for decades in proximity to the coal ash pits... " and yet failed to note that sampling of approximately 77 of the private wells failed to detect migration of ash -related constituents to any of the sampled wells despite such operation of the residential wells. Drs. Campbell and Spruill focus on interpretation of existing groundwater levels but do not opine on future groundwater levels and groundwater flow directions with a cap -in-place or source removal corrective action. As noted in Section 6 above, a cap -in-place remedy will alter groundwater levels from existing conditions due to a reduction of groundwater recharge. As a result, the groundwater mounding that currently exists beneath the ash basins will cease to exist and groundwater flow directions will be more clearly toward the river beneath the ash basins. Drs. Campbell and Spruill have numerous opinions regarding what they perceive to be flaws in the groundwater modeling analyses described in the CAP and CAP2 reports. As noted in Section 6, the model is only a tool that has been used to assist in the evaluation of the groundwater data collected at the Buck facility. The model is not intended to be an exact representation of the actual groundwater. The simplifications of the real groundwater system that have been made in developing the groundwater model do not alter the underlying groundwater data that have been collected at the facility. It is these data that provide the foundation for evaluating alternative corrective actions for groundwater. Drs. Campbell and Spruill opine that existing monitoring wells cannot provide any information about naturally -occurring constituents of interest and that no proper analyses have been conducted to establish natural background concentrations (2016b, page 1). The deficiencies that they note are in my opinion irrelevant to selecting an appropriate corrective action. In addition, it is my opinion that there are abundant data available for estimating the ranges of background concentrations of constituents of interest in the vicinity of the Buck facility and that existing monitoring data provide significant information about naturally -occurring constituents of interest. Drs. Campbell and Spruill also opine that the evaluations of on-site and off-site geology and hydrogeology is simplistic, incomplete and inadequate (2016a, page 5). The primary foundation for this opinion, based on my understanding of the report, is that groundwater flow in the bedrock aquifer is through fractures and the fractures have not been appropriately characterized. Groundwater flow in fractured bedrock at the fracture scale is complex, but at a 16 2.2- bVbVDObnr02 9� V220CIV1E2' IMC' �S larger scale groundwater flow in the bedrock is not complex. At the Buck facility, a large body of information on bedrock conditions has been obtained from the bedrock wells and borings at the facility and from private wells in the vicinity. As noted in Section 6, approximately 77 bedrock wells used for water supply in the vicinity of the facility have been sampled. The water -quality data from these wells clearly and unambiguously demonstrate that groundwater flow from the ash basins has not affected water quality in these wells. 17 2.2- bVbVDObnr02 9� V220CIV1E2' IMC' Section 8 References Abney, M.A., J.J. Hall, and J.R. Quinn. 2011. Assessment of Balanced and Indigenous Populations in the Yadkin River and High Rock Lake Near Buck Steam Station. NC0004774. Duke Energy. March. Anderson, M.P., W.W. Woessner, and R.J. Hunt. 2015. Applied Groundwater Modeling. Simulation of Flow and Advective Transport (2nd ed.): Elsevier. Barcelona, M.J., H.A. Wehrmann, M.R. Schock, M.E. Sievers, and J.R. Karny. 1989. Sampling Frequency for Ground -Water Quality Monitoring. U.S. Environmental Protection Agency. EPA/600/54-89/032. September. Brookins, D.G. 1988. Eh pH Diagrams for Geochemistry: Springer -Verlag Berlin Heidelberg. Campbell, S.K., and R.K. Spruill. 2016a. Expert Report Addendum #1 Buck Steam Station. May 12. Campbell, S.K., and R.K. Spruill. 2016b. Expert Report Buck Steam Station. February 29. Campbell, S.K., and R.K. Spruill. 2016c. Expert Report. Buck Steam Station (Federal). May 12. Duke Energy. 2016a. Duke Energy Coal Plants and Ash Management. https://www.duke- energy.com/pdfs/duke-energy-ash-metrics.pdf. June 2. Duke Energy. 2016b. Emergency Action Plan (EAP), Duke Energy Buck Station Ash Basin Dam. DUK-EAP-00-0001, Rev. 003, May 16. Duke Energy Corporation. 2011. Duke Energy Carolinas LLC - NPDES Permit Application Buck Steam Station - #NC0004774. February 28. Haley & Aldrich. 2015. Report on Evaluation of NC DEQ Private Well Data. Volumes 1 and 2. December. HDR Engineering Inc of the Carolinas. 2015a. Comprehensive Site Assessment Report. Buck Steam Station Ash Basin. August 23. HDR Engineering Inc of the Carolinas. 2015b. Corrective Action Plan Part 1. Buck Steam Station Ash Basin. November 20. HDR Engineering Inc of the Carolinas. 2016. Corrective Action Plan Part 2. Buck Steam Station Ash Basin. February 19. LeGrand, H.E. 2004. A Master Conceptual Model for Hydrogeological Site Characterization in the Piedmont and Mountain Region of North Carolina. A Guidance Manual. North Carolina Department of the Environmental and Natural Resources. North Carolina Department of Environment and Natural Resources. 2011. Permit NC0004774 - Permit for Duke Energy to Discharge Wastewater Under the National Pollutant Discharge Elimination System. Buck Steam Station. December 2. 2.2- bVbVDObnr02 9� V220CIV1E2' JWC' SSU North Carolina Department of Environmental Quality. 2016. Press Release: "State Releases Deadlines for Coal Ash Pond Closures, Will Request Changes to Coal Ash Law". May 18. Links for map of the proposed classifications and table of risk factors for classification are: http://portal.ncdenr.org/c/document_ library/get_file?p_l_id=1169848&folderld=2688409 6&name=DLFE-125497.pdf, and http://portal.ncdenr.org/c/document—library/get—file?p—l—id=l 169848&folderld=2688409 6&name=DLFE-125496.pdf. Oze, C., D.K. Bird, and S. Fendorf. 2007. Genesis of Hexavalent Chromium from Natural Sources in Soil and Groundwater: PNAS 104, no. 16: 6544-6549. Parette, R., and Matson & Associates. 2016. Opinions on the Appropriateness of Monitored Natural Attenuation in Conjunction with Cap -in -Place at the Buck Steam Station. May 13. Pippin, C.G., M.J. Chapman, B.A. Huffman, M.J. Heller, and M.E. Schelgel. 2008. Hydrogeologic Setting, Ground -Water Flow, and Ground -Water Quality at the Langtree Peninsula Research Station, Iredell County, North Carolina, 2000-2005. Scientific Investigations Report. U.S. Geological Survey. 2008-5055. U.S. Environmental Protection Agency (USEPA). 1999. Use of Monitored Natural Attenuation at Superfund, RCRA Corrective Action, and Underground Storage Tank Sites. 9200.4-17P. Washington, D.C. April 21. U.S. Environmental Protection Agency (USEPA). 2009. Statistical Analysis of Groundwater Monitoring Data at RCRA Facilities Unified Guidance. EPA 530-R-09-007. March. U.S. Environmental Protection Agency (USEPA). 2015a. Use of Monitored Natural Attenuation for Inorganic Contaminants in Groundwater at Superfund Sites. Directive 9283.1-36. August. U.S. Environmental Protection Agency (USEPA). 2015b. Hazardous and Solid Waste Management Systems: Disposal of Coal Combustion Residuals from Electric Utilities. Federal Register. Vol. 80 No. 74. April 17. Winters, T.C. 1976. Numerical Simulation Analysis of the Interaction of Lakes and Ground Water. Professional Paper 1001. U.S. Geological Survey. Wright, M.T., and K. Belitz. 2010. Factors Controlling the Regional Distribution of Vanadium in Groundwater: Ground Water 47, no. 4: 515-525. 19 FIGURES 2.2- bVbVDObnrO2 9 V220CIVlE2' jWC' Yadkin River (High Rock Lake) AB -7S 600 A AB-7SL 2000 AB -5S AB-5SL AB -8S 464- 800 1800 8800 AB -4S r 150 AB -2S 1830 A AB-2SL 3920 AB -3S 2600 Grant Rd j s at �� ye t aures St Boron Concentration 0 A 'a Figure 1 Boron Concentration 0 A Yadkin River (High Rock Lake) GWA-9S �r,�4M-2S 303 W 487 0 0 t aures St Figure 2 2.2- bVbVDObnrO2 9 V220CIVJ.E2' [MC' A GWA-3S 62.A A MW -5S 259 Yadkin River (High Rock Lak e p� GWA-9D _ Jhfa t't 266 r A Boron Concentration 0 A MW -1 D 593 GWA-10D 90 A Figure 3 2.2- bVbVDObnrO2 9 V220CIV.LE2' [MC' A MW -5D 388 O Grant Rd Boron Concentration D IF O 41jq-1 �9t Yadkin River (High Rock Lake) 0 GWA-9BR 230 2.2- bVbVDObnrO2 9 V22OCIVIE2' IMC' ® Is GWA-SBRU 350 A MW -11 D 0 0 AB-9BR 1320 420 A AB-SBRU AB-8BRU 120 65.3 ® A 63.6 63.6A 5 — 0 des St B 6� O ;J•k � O Figure 4 B Grant Rd O C n TABLES 2.2- bV6VD06nrO@ g br@20CiviE@' IVIG' Table 1 Monitoring Wells with Boron Concentrations Greater than 50 ug/L and Exccedances of Groundwater Criteria for Other Constituents of Interest Well B Sb As Cr Constituents of Interest (ug/L) Co Fe Mn Se Comment TI v SO4 TDS Criteria 700 1 10 10 1 300 50 20 0.2 20 250,000 500,000 2L Standard or IMAC AB -10D 1900 17.4 27 130 A13-1 D 1500 J AB-2BR 110 1.3 J 23.1 A13 -2D 630 3.2 360 130 AB-513RU 120 26.5 J+ 27.6 J+ 30.6 1.7 J+ 42.8 A13-76RU 140 1.8 17.9 AB-8BRU 52 AB -8D 83 1.2 11.9 AB-9BR 420 12.3 26 A13-96RU 790 300 A13-913 1000 1 AS -1 D 360 AS -1 S 3000 J 356 4100 21 0.2 703000 1240000 GWA-3S 62 1.9 3000 GWA-41D 220 59 GWA-4S 260 1.1 50 GWA-513RU 350 310 180 GWA-913R 230 2.3 GWA-9D 220 1.4 683 120 GWA-9S 280 67.4 2100 GWA-18D 100 15.2 MW -11D 1100 MW -11S 410 1.8 280 MWAD 510 MWAS 730 22.3 MW -3D 640 60 MW -3D 630 MW -3S 860 J+ 17.9 740 1200 MW -3S 920 18.4 720 1200 MW -4D 630 MW -4S 490 70 MW -5D 340 MW -5S 220 Notes: Maxium dissovled concentrations reported in CSA sampling. Only concentrations greater than groundwater critiera are listed for constituents others than boron. APPENDIX A Appendix A Curriculum Vitae of Charles B. Andrews and Rate of Compensation CHARLES B. ANDREWS Hydrologist AREAS OF EXPERTISE ■ Simulation of Groundwater and Surface -Water Flow / Contaminant Fate and Transport ■ Water Resource and Water Rights Evaluations SUMMARY OF QUALIFICATIONS Dr. Andrews is nationally known for his creative solutions to difficult water -resource problems. His areas of expertise include the assessment and remediation of contaminated sites; formulation of water -resource projects; assessment of surface -water and groundwater flow and quality conditions at hazardous waste sites; design of water remediation systems; and development of new and modification of off-the-shelf numerical simulation models for adaptation to specific field projects. He has provided technical guidance to significant water -rights litigation. Dr. Andrews is a frequently requested member of groundwater advisory panels for the evaluation of state-of- the-art hydrology and for pioneering research and evaluation of contaminant transport in the subsurface. He is the author and co-author of numerous publications on modeling of groundwater flow and transport of chemical constituents, and the use of analytical models in identifying appropriate remediation alternatives for a site. REPRESENTATIVE EXPERIENCE S.S. Papadopulos & Associates, Inc., Bethesda, MD ■ Agricultural Issues, Wisconsin — Worked with operators and DAFOs of large irrigated farms and dairies to develop crop -rotation and nutrient - management plans to minimize potential for nitrogen contamination of groundwater. For one project involving the conversion of 4000 acres from pine plantation to irrigated agriculture, developed a detailed nitrogen balance of the expected agricultural practices and a groundwater transport model. Subsequently used these tools to develop cropping and nutrient application schedules that minimize potential for nitrogen contamination of groundwater. These evaluations were incorporated into an environmental impact statement for the project. Provided several presentations regarding this work to State regulatory agency and growers' associations. 2'2' bV6VD06nr oe 8F b220CIb.LE2' INC' • Contaminated Site Investigation and Remediation ■ Expert Testimony ■ Peer Review YEARS OF EXPERIENCE: 30+ EDUCATION PhD, Geology, University of Wisconsin, Madison, 1978 MS, Geology, University of Wisconsin, Madison, 1976 MS, Water Resources, University of Wisconsin, Madison, 1974 BA, Geology, Carleton College, 1973 American University of Beirut, Beirut, Lebanon,1971-1972 REGISTRATIONS Registered Geologist: Alabama No. 1175 California No. 3853 Georgia No. PGO01689 Illinois No. 196001360 Mississippi No. 859 Washington No. 2841 PROFESSIONAL HISTORY S.S. Papadopulos & Associates, Inc., Principal, 1984 to present President, 1994-2012 South University of Science and Technology of China, Shenzhen Visiting Professor, 2015 to present Woodward - Clyde Consultants Hydrogeologist and head of Groundwater Section, 1980-1984 Northern Cheyenne Indian Tribe Scientist, 1978-1980 Wisconsin State Government Dept. of Justice and Dept. of Natural Resources, Consultant, 1977-1978 University of Wisconsin, Madison Dept. of Geology & Geophysics, Research Assistant, 1975-1978 Dept. of Water Resources, Researcher, 1974-1975 Onondaga Lake, Syracuse, New York —Headed the groundwater modeling effort for design of remedial alternatives for this reputed -to -be the most contaminated lake in the U.S. Remediation costs 2'2' bV6VD06nr oe 8F b220CIVIE2' INC' CHARLES B. ANDREWS Hydrologist Page 2 projected to cost several hundreds of millions of dollars. Interacted frequently with and made many presentations to the New York State Department of Environmental Conservation. This work is ongoing. • Large Industrial Site, Georgia — Conducted a detailed field and laboratory evaluation of the leachability of PCBs from contaminated soils at this site. Developed innovative methods to distinguish dissolved- and particulate -phase PCBs in leachate from batch tests. • U.S. Army Corps of Engineers, Washington — Conducted detailed modeling evaluations of seepage through the Howard Hanson Dam on the Green River. The evaluations were conducted to assist in evaluations of dam stability and actions required to improve that stability as dam failure would have large impacts on the lower river valley, including the Lower Duwamish Waterway. ■ Oregon Department of Environmental Quality and Cascade Corporation, Oregon — Assisted the Department of Environmental Quality during the RI/FS process for the East Multnomah County Groundwater Contamination Superfund Site and designed the extensive pump -and -treat system for the site. In recent years, provided assistance to Cascade Corporation, one of the PRPs, on methods to enhance remedial progress. ■ Confidential Client, Michigan —Conducted a detailed laboratory evaluation of analytical methods for phenols in water samples. Determined that certain analytical methods were prone to false - positive readings due to reactions with dissolved natural organic matter during the analytical procedure. Identified the probable reaction pathways for the reactions that create phenols from the dissolved organic matter. • Williams Companies —Participated as a technical expert for a major pipeline company in a year- long Consent Decree negotiations with the U.S. Dept. of Justice regarding soil and groundwater contamination issues at 30 compressor station sites. Developed a comprehensive framework, which was incorporated in the Consent Decree, for efficient, cost-effective investigation and remediation of compressor stations. Subsequent to Consent Decree, provided (and continue to provide) technical oversight for site investigation and remediation. • Major Bottled -Water Company, Michigan —Providing on-going groundwater consulting services for the identification and development of spring -water sources. This work involves development of groundwater models to identify potential production rates, optimal pumping rates and locations, and environmental effects of water production. Developed long-term monitoring plans and served as expert witness in litigation related to development and operation of spring -water sources. • Professional Review and Services, miscellaneous U.S. sites —Served as Chair of External Peer Review Panel for Frenchman Flat CAU at the Nevada Test Site (2010). Served on a review panel for the Hanford (Washington) site -wide groundwater flow -and -transport model (1989-2001). Developed a groundwater model of the A- and M- areas at the Savannah River site, South Carolina, (1985-1986). ■ Texas Eastern Pipeline Company, Eastern U.S. —Directed a study to evaluate the mobility and fate of polychlorinated biphenyl compounds (PCBs) in the subsurface for over 30 contaminated sites. These studies involved laboratory and field experiments to investigate the interactions between PCBs and the subsurface materials, and to investigate the potential degradation of PCBs in the subsurface. Long-term monitoring was selected as the appropriate remedial action at all the sites. ■ New Mexico Attorney General: Hueco Bolson and the Mesilla Basins, New Mexico — Evaluated the long-term availability of groundwater and the associated water -quality problems of these large regional aquifers in southern New Mexico. Served as an expert witness in litigation involving the proposed development of large water supplies from these basins. 2'2' bV6VD06nr oe 8F b22OCIVIE2' INC' CHARLES B. ANDREWS Hydrologist Page 3 • Industrial Sites, California and New Jersey —Managed remediation activities, including remedial investigations, feasibility studies, remedial design and implementation, for industrial sites that are extensively contaminated with arsenic and associated heavy metals. Several of these investigations involved the evaluation of geochemical parameters that govern arsenic mobility in the subsurface and groundwater/surface-water interactions. Woodward -Clyde Consultants, San Francisco and Walnut Creek, California Senior Project Manager of the 15 -person Ground -Water Group: Responsible for water -resource business development, technical review of all water -resource projects, and staff administration. As Project Manager and Hydrology Task Leader, examples of projects included the development of groundwater flow models of Madison Aquifer in Wyoming and the San Juan Basin in New Mexico; analysis of reservoir -induced seismicity at the Aswan Dam; and development of a groundwater model and remediation plan for a 12,000 -acre site having 200 major source areas. Responsible for developing the firm's state -of -the -practice capabilities in quantitative hydrology. Northern Cheyenne Indian Tribe, Lame Deer, Montana Directed and helped establish a comprehensive surface -water and groundwater monitoring program, and established and managed the tribal computer system. Trained tribal members in the operation and management of the hydrologic monitoring system and the computer system. Participated in numerous administrative and legislative proceedings as an advocate for tribal management of the reservation's natural resources. Wisconsin Department of Justice and Department of Natural Resources, Madison, Wisconsin Served as an expert witness for several judicial and administrative proceedings on cases involving groundwater contamination and wetland drainage. University of Wisconsin, Department of Geology and Geophysics, Madison, Wisconsin Researched the impacts of heated -water seepage from a power plant cooling lake. Developed a finite -element computer code to simulate water and heat transfer in shallow unconfined aquifers, and designed and maintained an extensive field monitoring program to collect the data needed for model verification. University of Wisconsin, Department of Water Resources, Madison, Wisconsin Conducted research that was funded by the U.S. Environmental Protection Agency -Denver, on the impact of oil shale development to the groundwater and surface -water resources of northwestern Colorado. APPOINTMENTS Trustee and Treasurer, Geological Society of America, 200 to present Board of Visitors, Department of Geology, University of Wisconsin, 2004-2012 Water -Quality Advisory Group, Chairman, Montgomery County, Maryland, 2003-2007 Associate Editor, Ground Water, 1998-2013 Board of Directors of the Association of Groundwater Scientists and Engineers Division of the National Ground Water Association, 1997-2001 National Research Council Committee on Groundwater Cleanup Alternatives, National Academy of Sciences, 1991-1994 2'2' bV6VD06nr oe 8F b220CIVIE2' INC' CHARLES B. ANDREWS Hydrologist Page 4 National Research Council Committee on Groundwater Modeling Assessment, National Academy of Sciences, 1987-1988 PROFESSIONAL SOCIETIES American Chemical Society National Ground Water Association American Association for the Advancement of Science Geological Society of America PUBLICATIONS & PRESENTATIONS Huang, X., C.A. Andrews, J. Liu, Y. Yao, C. Liu, S.W. Tyler, J.S. Selker, and C. Zheng. (in press). Assimilation of Temperature and Hydraulic Gradients for Quantifying the Spatial Variability of Streambed Hydraulics. Water Resources Research. Paper # 2015WR018408RR. Andrews, C., 2011. How Much Modeling is Enough? Presentation at MODFLOW and More 2011: Integrated Hydrologic Modeling. International Groundwater Modeling Center (IGWMC), Colorado School of Mines, Maxwell, P., Hill, and Zheng, eds. Andrews, C., 2011. Urban Recharge Myth: Case Study of Montgomery County, Maryland. Presentation at the 2011 Ground Water Summit and 2011 Ground Water Protection Council Spring Meeting. National Ground Water Association, Baltimore, MD. Root, R.A., D. Vlassopoulos, N.A. Rivera, M.T. Rafferty, C. Andrews, and P.A. O'Day, 2009. Speciation and Natural Attenuation of Arsenic and Iron in a Tidally Influenced Shallow Aquifer: Geochimica et Cosmochimica Acta, Science Direct. Johnson, T., C. Andrews, and M. Hennessey, 2009. Development of Chloride Profiles to Estimate Groundwater Discharge for Cap Design in Onondaga Lake. Presentation at the Fifth International Conference on Remediation of Contaminated Sediments, Jacksonville, FL. February 2-5, 2009. Barth, G., and C. Andrews, 2009. Practical Problems, Practical Solutions. Presentation at the National Groundwater Association's Annual Groundwater Summit, Tucson, AZ, April 19-23, 2009. Andrews, Charles, 2008. One Hydrogeology —A New Paradigm for Model Construction: Modeling with Google Earth. Presentation at MODFLOW and More 2008: Ground Water and Public Policy Conference, May 18-21, 2008, Golden, CO. Andrews, C.B., 2008. Review of "Effective Groundwater Model Calibration: With Analysis of Data, Sensitivities, Predictions, and Uncertainty": Ground Water, v. 46, no. 1, p. 5. Spiliotopoulos, A., and C.B. Andrews, 2007. Analysis of Aquifer Test Data - MODFLOW and PEST. in Groundwater and Wells.(3rd ed.). Sterrett, R.J., ed. Johnson Screens, New Brighton, MN, 812 p. Karanovic, M., C.J. Neville, and C.B. Andrews, 2007. BIOSCREEN-AT: BIOSCREEN with an Exact Analytical Solution: Ground Water, v. 45, no. 2, pp. 242-245. Andrews, C.B., and G. Swenson, 2006. Simulation of Brine Movement into Onondaga Lake. Presentation at MODFLOW and More 2006: Managing Ground -Water Systems. International Ground Water Modeling Center, Colorado School of Mines Golden, CO, May 22-24, 2006. v. 2, pp. 480-483. Neville, C.J., and C.B. Andrews, 2006. Containment Criterion for Contaminant Isolation by Cutoff Walls: Ground Water, v. 44, no. 5, September -October, pp. 682-686. Spiliotopoulos, A.A., and C.B. Andrews, 2006. Analysis of Aquifer Test Data - MODFLOW and PEST. Presentation at MODFLOW and More 2006: Managing Ground -Water Systems. 2'2' bV6VD06nr oe 8F b220CIVIE2' INC' CHARLES B. ANDREWS Hydrologist Page 5 International Ground Water Modeling Center, Colorado School of Mines, Golden, CO, May 22-24, 2006. v. 2, pp. 569-573. Vlassopoulos, D., N. Rivera, P.A. O'Day, M.T. Rafferty, and C.B. Andrews, 2005. Arsenic Removal by Zerovalent Iron: A Field Study of Rates, Mechanisms, and Long -Term Performance. in Advances in Arsenic Research: Integration of Experimental and Observational Studies and Implications for Mitigation. O'Day, P., D. Vlassopoulos, X. Meng, and L. Benning, eds. ACS Symposium Series, v. 915. Washington, DC: American Chemical Society, pp. 344-360. Andrews, C., and C. Neville, 2003. Ground Water Flow in a Desert Basin: Challenges of Simulating Transport of Dissolved Chromium. Ground Water, v. 41, no. 2, pp. 219-226. Rafferty, M.T., C.B. Andrews, D. Vlassopoulos, D. Sorel, and K.M. Binard, 2003. Remediation of an Arsenic Contaminated Site. Presentation at the 226th American Chemical Society National Meeting, September 7-11, 2003, New York City, NY. Vlassopoulos, D., C.B. Andrews, M. Rafferty, P.A. O'Day, and N.A. Rivera Jr., 2003. In Situ Arsenic Removal by Zero Valent Iron: An Accelerated Pilot Test Simulating Long -Term Permeable Reactive Barrier Performance. Presentation at the 226th American Chemical Society National Meeting, September 7-11, 2003, New York City, NY. Sorel, D., C.J. Neville, M.T. Rafferty, K. Chiang, and C.B. Andrews, 2002. Hydraulic Containment Using Phytoremediation and a Barrier Wall to Prevent Arsenic Migration. In Proceedings of the Third International Conference on Remediation of Chlorinated and Recalcitrant Compounds, May 20-23, 2002, Monterey, CA. Gavaskar, A.R., and A.S.C. Chen, eds. Battelle Press. Vlassopoulos, D., J. Pochatila, A. Lundquist, C.B. Andrews, M.T. Rafferty, K. Chiang, D. Sorel, and N.P. Nikolaidis, 2002. An Elemental Iron Reactor for Arsenic Removal from Groundwater. in Proceedings of the Third International Conference on Remediation of Chlorinated and Recalcitrant Compounds, May 20-23, 2002, Monterey, CA. Gavaskar, A., and A.S.C. Chen, eds. Battelle Press. Andrews, C., and C. Neville, 2001. Groundwater Flow in a Desert Basin: Complexity and Controversy. in Proceedings of MODFLOW 2001 and Other Modeling Odysseys, September 11-14, 2001, International Groundwater Modeling Center, Colorado School of Mines, Golden, CO, pp.770-775. Andrews, C.B, 2000. The Great American Experiment: Pump -and -Treat for Groundwater Cleanup. in Proceedings of the International Symposium on Groundwater Contamination, Japanese Association of Groundwater Hydrology, Tokyo, Japan. June 26, 2000. Andrews, C.B, 2000. The Meaning of Success in Assessing Groundwater Remediation. Presentation at the Western Pacific Geophysics Meeting, June 27-30, 2000, Tokyo, Japan. Eos, v. 81, no. 22, May 30, 2000. Andrews, C.B., and D. Vlassopoulos, 2000. Modeling the Migration of Arsenic in Groundwater: Understanding the Processes. Geological Society of America, Annual Meeting, October 2000, Reno, NV. in Geological Society of America Abstracts with Programs, A406-7. Vlassopoulos, D., and C.B. Andrews, 2000. The Intertwined Fate of Iron and Arsenic in Contaminated Groundwater Entering a Tidal Marsh, San Francisco Bay. Invited Speaker Presentation at the National Ground Water Association Theis 2000 Conference on Iron in Groundwater, September 15-18, 2000, Jackson Hole, WY. Lolcama, J.L., and C.B. Andrews, 1999. Catastrophic Flooding of a Quarry in Karstified Dolomite (Abstract). Presentation at the NGWA National Convention and Exposition, December 3-6, 1999, Nashville, TN. in Ground Water Supply Issues in the Next Century, 1999 Abstract Book. Nashville, TN: National Groundwater Association. 2'2' bV6VD06nr oe 8F b220CIVIE2' INC' CHARLES B. ANDREWS Hydrologist Page 6 Vlassopoulos, D., C. Andrews, R. Hennet, and S. Macko, 1999. Natural Immobilization of Arsenic in the Shallow Groundwater of a Tidal Marsh, San Francisco Bay. Presentation at the American Geophysical Union 1999 Spring Meeting, May 31 -June 4, Boston, MA. Andrews, C.B, 1998. MTBE: A Long -Term Threat to Ground Water Quality: Ground Water, v. 36, no. 5, pp. 705-706. Hennet, R., D.A. Carleton, S.A. Macko, and C.B. Andrews, 1997. Environmental Applications of Carbon, Nitrogen, and Sulfur Stable Isotope Data: Case Studies (abstract). Invited Speaker Presentation at the Geological Society of America Annual Meeting, Salt Lake City, UT, November 1997. Zhang, Y., C. Zheng, C.J. Neville, and C.B. Andrews, 1996. ModIME User's Guide: An Integrated Modeling Environment for MODFLOW, PATH3D, and MT3D. Version 1.1. Bethesda, MD: S.S. Papadopulos & Associates, Inc. Larson, S.P., C.B. Andrews, and C.J. Neville, 1995. Parameter Estimation in Groundwater Modeling: Research, Development, and Application (abstract). American Geophysical Union (AGU) Spring Meeting, Baltimore, May 30 -June 2, 1995, Hydrology Sessions. S145, Abstract H51C-02 0835h. Andrews C.B. (co-author), 1994. Chapter 3—Performance of Conventional Pump -and -Treat Systems, and Chapter 5 --Characterizing Sites for Ground Water Cleanup. in Alternative Ground Water Cleanup. Washington, DC: National Academy Press. Hennet, R.J.-C., and C.B. Andrews, 1993. PCB Congeners as Tracers for Colloid Transport in the Subsurface --4 Conceptual Approach. in Manipulation of Groundwater Colloids for Environmental Restoration. Ann Arbor, MI: Lewis Publishers, pp. 241-246. Zheng, C., G.D. Bennett, and C.B. Andrews, 1992. Reply to the Preceding "Discussion by Robert D. McCaleb of'Analysis of Ground -Water Remedial Alternatives at a Superfund Site'": Ground Water, v. 30, no. 3, pp. 440-442. Zheng, C., G.D. Bennett, and C.B. Andrews, 1991. Analysis of Ground -Water Remedial Alternatives at a Superfund Site: Ground Water, v. 29, no. 6, pp. 838-848. Andrews C.B. (co-author), 1990. Chapter 5 --Experience with Contaminant Flow Models in the Regulatory System. in Ground Water Models: Scientific and RegulatoryApplications. Washington, DC: National Academy Press. Andrews, C.B., D.L. Hathaway, and S.S. Papadopulos, 1990. Modeling the Migration and Fate of Polychlorinated Biphenyls in the Subsurface. in Proceedings of the PCB Forum, Second International Conference for the Remediation of PCB Contamination, April 2-3, 1990, Houston, TX, pp. 64-82. Hathaway, D., and C. Andrews, 1990. Fate and Transport Modeling of Organic Compounds from a Gasoline Spill. in Proceedings of Petroleum Hydrocarbons and Organic Chemicals in Ground Water; Prevention, Detection, and Restoration, National Water Well Association and American Petroleum Institute, Houston, TX, October 31 -November 2, 1990. Ground Water Management, v. 4, pp. 563-576. Stephenson, D.E., G.M. Duffield, D.R. Russ, C.B. Andrews, and E.C. Phillips, 1989. Practical Use of Models in Ground Water Assessment and Protection Programs at the Savannah River Site: Three Case Histories. Presentation at the Joint USA/USSR Conference on Hydrogeology, Moscow, USSR, June 30 -July 11, 1989. Andrews, C.B., and S.P. Larson, 1988. Evolution of Water Quality in the Lower Rio Grande Valley, New Mexico. Eos, v. 69, no. 16, p. 357. 2'2' bV6VD06nr oe 8F b220CIVIE2' INC' CHARLES B. ANDREWS Hydrologist Page 7 Larson, S.P., C.B. Andrews, M.D. Howland, and D.T. Feinstein, 1987. Three -Dimensional Modeling Analysis of Groundwater Pumping Schemes for Containment of Shallow Groundwater Contamination. Presentation at Solving Ground Water Problems with Models, Association of Ground Water Scientists and Engineers, Denver, CO, February 10-12, 1987. in Solving Ground Water Problems with Models: An Intensive Three -Day Conference and Exposition Devoted Exclusively to Ground Water Modeling. Vol. 1. Dublin, OH: National Water Well Association, pp. 517-536. February 11. Looney, B.B., R.A. Field, G.B. Merrell, G. Duffield, and C.B. Andrews, 1987. Analyses of the Validity of Analytical Models Used for Assessment of Forty -Five Waste Site Areas: Subsurface Flow and Chemical Transport. in Solving Ground Water Problems with Models. Dublin, OH: National Water Well Association, pp. 954-982. Stephenson, D.E., B.B. Looney, C.B. Andrews, and D.R. Buss, 1987. Three -Dimensional Simulation of Groundwater Flow and Transport of Chemical and Low -Level Radioactive Constituents within Two Production Areas of the Savannah River Plant. in Proceedings of the 9th Annual Low -Level Radioactive Waste Conference, U.S. Department of Energy, Washington, DC, pp. 472-481. Auerbach, S.I., C. Andrews, D. Eyman, D.D. Huff, P.A. Palmer, and W.R. Uhte, 1984. Report of the Panel on Land Disposal. in Disposal of Industrial and Domestic Wastes: Land and Sea Alternatives. Washington, DC: National Academy Press, pp. 73-100. Andrews, C.B., 1983. Hydrogeology in North America —1932 to 1982. in The Revolution in Earth Sciences: Advances in the Past Half -Century. Boardman, S., ed. Kendall/Hunt Publishing Company. Andrews, C.B., 1979. Impacts of Coal -Fired Power Plants on Local Ground -Water Systems. Wisconsin Power Plant Impact Study. U.S. Environmental Protection Agency. EPA 600/3-80- 079. p. 203. Andrews, C.B., 1979. Statement of Dr. Charles Andrews, Hydrologist, Northern Cheyenne Tribe. Hearings before the Select Committee on Indian Affairs. U.S. Senate, 96th Congress, pp. 412- 432. Andrews, C.B., and M.P. Anderson, 1979. Thermal Alteration of Groundwater Caused by Seepage from a Cooling Lake: Water Resources Research, v. 15, no. 3, pp. 595-602. Andrews, C.B., W. Woessner, and T. Osborne, 1979. The Impacts of Coal Strip Mining on the Hydrogeologic System of the Northern Great Plains —Case Study of Potential Impacts on the Northern Cheyenne Reservation. Journal of Hydrology, v. 43, pp. 445-467. Andrews, C.B., 1978. The Impact of the Use of Heat Pumps on Groundwater Temperatures. Ground Water, v. 16, no. 6, pp. 437-443. Andrews, C.B., and M.P. Anderson, 1978. The Impact of a Power Plant on the Groundwater System of a Wetland. Ground Water, v. 16, no. 2, pp. 105-111. Andrews, C.B., and E. Quigley, 1975. Designing and Maintaining Ponds for Swimming. University of Wisconsin -Madison, Extension Publication G2678, p. 22. DEPOSITION AND TESTIMONY EXPERIENCE DEPOSITIONS 2015 Duke Energy Progress, Inc. v. N.C. Department of Environment and Natural Resources, Division of Water Resources. State of North Carolina, Wake County in the Office of Administrative Hearings. Case No. 15 HER 02581. July 31. 2'2' bV6VD06nr oe 8F b220CIVIE2' INC' CHARLES B. ANDREWS Hydrologist Page 8 2014 Emhart Industries, Inc. vs. New England Container Company, Inc., et al. vs. United States Department of the Air Force, et al. vs. Black & Decker, Inc. United States District Court for the District of Rhode Island. C.A. 06-218S and C.A 11-023S (Consolidated). November 17-18. 2014 Emhart Industries, Inc. vs. New England Container Company, Inc., et al. vs. United States Department of the Air Force, et al. vs. Black & Decker, Inc. United States District Court for the District of Rhode Island. C.A. 06-218-S and C.A 11-023-S (Consolidated). May 28. 2012 Commissioner of the Department of Planning and Natural Resources, Alicia V. Barnes, et al. Century Alumina Company, et al. District Court of the Virgin Islands Division of St. Croix. Civil No. 2005-0062. June 28-29. 2010 United States Virgin Islands Department of Planning and Natural Resources vs. St. Croix Renaissance Group, L.L.L.P., et al. District Court of the Virgin Islands Division of St. Croix. Civil No. 2007/114. October 20. 2010 United States Virgin Islands Department of Planning and Natural Resources v. St. Croix Renaissance Group, L.L.L.P., et al. District Court of the Virgin Islands Division of St. Croix. Civil No. 2007/114. October 22. 2010 New Jersey Department of Environmental Protection, The Commissioner of the New Jersey Department of Environmental Protection and the Administrator of the New Jersey Spill Compensation Fund vs. Essex Chemical Corporation. Superior Court of New Jersey Law Division: Middlesex County. Docket No.: MID -L-5685-07. February 22. 2009 United States of America vs. Norfolk Southern Railway Company. U.S. District Court for the District of South Carolina, Aiken Division. Civil Action No. 1:08 -CV -01707 -MBS. August 5. 2009 Michigan Citizens for Water Conservation, et al. vs. Nestle Waters North America, Inc. State of Michigan Mecosta County Circuit Court. File No. 01 -14563 -CE. February 11 and March 6. 2008 The Gillette Company vs. Onebeacon America Insurance Company, et al. Commonwealth of Massachusetts Superior Court. 05 -5102 -BLS. December 4. 2008 Brian Wayne Meixner et al. vs. Emerson Electric Co. et. al. U.S. District Court for the District of South Carolina, Aiken Division. 06 -CV -01359 -MBS. April 29. 2007 Glenn Gates and Donna Gates v. Rohm & Haas Company, et al. U.S. District Court for the Eastern District of Pennsylvania. Civil Action No. 2:06 -CV -01743 -GP. November 16, 19. 2007 Methyl Tertiary Butyl Ether (MTBE) Products Liability Litigation, County of Suffolk and Suffolk County Water Authority vs. Amerada Hess Corporation et al., United Water New York, vs. Amerada Hess Corporation et al. U.S. District Court Southern District of New York. 04 CIV. 5424 and 04 CIV. 2389. November 27, 28. 2007 Kay Ryan Corley, et al. v. Colonial Pipeline Company, et al. Hale County Circuit Court, Alabama. CV -2005-138. September 6-7. 2003 American Home Products Corporation vs. Adriatic Insurance Company. Superior Court of New Jersey Law Division: Hudson County. Docket No. HUD -L-5002-92. April 29. 2003 H. Todd Brinckerhoff, Jr., Harriet B. Haslett and MBM Company I, LLC vs. Shell Oil Company and Motiva Enterprises, LLC. U.S. District Court, Southern District of New York. Civil Action No. 02cv939. March 27. 2'2' bV6VD06nr oe 8F b220CIVIE2' INC' CHARLES B. ANDREWS Hydrologist Page 9 2003 Bernice Samples et al. vs. Conoco, Inc.; Agrico Chemical Company and Escambia Treating Company, Inc. Circuit Court of the First Judicial Circuit in and for Escambia County, Florida. No. 01 -631 -CA -01. March 18. 2002 Michigan Citizens for Water Conservation et al. vs. Nestle Waters North America, Inc. et al. State of Michigan in the Circuit Court for the County of Mecosta. Case No. 01 -14563 -CE. October 14. 2001 JBG/JER Shady Grove, LLC vs. Eastman Kodak Company. Circuit Court for Montgomery County, Maryland. Civil No. 214877. October 25. 1999 Associated Aviation Underwriters, Inc. vs. Purex Industries, Inc. et al. Superior Court of the State of California for the County of Los Angeles. No. ECO21744. August 9.\ 1999 Flintkote Company and Genstar Corp. vs. Liberty Mutual Insurance Company et al. Superior Court of New Jersey, Law Division, Bergen County. Docket No. 10288-97. March 26. 1998 GenCorp Inc. vs. Adriatic Insurance. Superior Court of New Jersey. Case No. 5:95CV 2464. September. 1997 C -I -L Corporation of America and Marsulex, Inc. vs. NL Industries, Inc. et al. U.S. District Court, District of New Jersey. Civil Action No. 93-2157 (WHW). January 21. 1995 Freehold -Carthage, Inc. vs. Lumbermans Mutual Casualty et al. vs. Hartford Insurance Company vs. Minnesota Mining and Manufacturing Company. Superior Court of New Jersey. Docket No. L-56812-90. 1995 Hughes Aircraft Company vs. Brian Eustace Beagley et al. Superior Court of the State of California, County of Los Angeles. No. BC062120. February 10. 1993 Martin Marietta Corporation vs. Aetna Casualty & Surety et al. Superior Court of the State of California for the County of Los Angeles. Case No. C610358. 1992 In re: Demand for Arbitration filed by Richard and Susan Ritchie and Exxon Corporation. State of New Jersey, Department of Environmental Protection. Damage Claim No. 86-54- 0033. February 29. TESTIMONY 2015 Emhart Industries, Inc. v. New England Container Company, Inc., et al. and Emhart Industries, Inc. v. United States Department of the Air Force, et al. v. Black & Decker, Inc., et al. United States District Court for the District of Rhode Island. C.A. Nos.: 06-218 S and 11-023 S. June 25. 2014 In the Matter of a Conditional High Capacity Well Approval for Two Potable Wells to be Located in the Town of New Chester, Adams County, Issued to New Chester Dairy, Inc. and Milk Source, Holding, LLC. Case No. DNR -13-011. State of Wisconsin Division of Hearings and Appeals. January 16-17. 2013 In the Matter of a Conditional High Capacity Well Approval for Two Potable Wells to be Located in the Town of Richfield, Adams County, Issued to Milk Source Holding, LLC. Case Nos. IH -12-03, IH -12-04, IH -12-05, and IH -12-08. State of Wisconsin Division of Hearings and Appeals. June 24, 25 and December 16, 20. 2010 Branham v. Rohm & Hass Company et al. Court of Common Pleas of Philadelphia County. October 12-18. 2'2' bV6VD06nr oe 8F b220CIVIE2' INC' CHARLES B. ANDREWS Hydrologist Page 10 2010 New Jersey vs. Essex Chemical Corporation. Superior Court of New Jersey Law Division: Middlesex County. Docket No.: MID -L-5685-07. March 19. 2008 Attorney General of the State of Oklahoma and Oklahoma Secretary of the Environment vs. Tyson Foods Inc. et al. U.S. District Court for the Northern District of Oklahoma. 4:05-CV- 00329-TCK-SAJ. March 10. 2003 Michigan Citizens for Water Conservation et al. vs. Nestle Waters North America Inc. et al. State of Michigan in the Circuit Court for the County of Mecosta. 01 -14563 -CE. June 6. 2003 Michigan Citizens for Water Conservation et al. vs. Nestle Waters North America Inc. et al. State of Michigan in the Circuit Court for the County of Mecosta. 01 -14563 -CE. May 21. 2003 Michigan Citizens for Water Conservation et al. vs. Nestle Waters North America Inc. et al. State of Michigan in the Circuit Court for the County of Mecosta. 01 -14563 -CE. May 19. 2001 JBG/JER Shady Grove, LLC vs. Eastman Kodak Company. Circuit Court for Montgomery County, Maryland. Civil No. 214877. December 13. 1995 Anderson et al. vs. Pacific Gas and Electric Company. Superior Court of the State of California for the County of San Bernardino. Case No. BCV00300. July. 1995 Hughes Aircraft Company vs. Brian Eustace Beagley et al. Superior Court of the State of California, County of Los Angeles. No. BC062120. 1995 Anderson et al. vs. Pacific Gas and Electric Company. Superior Court of the State of California for the County of San Bernardino. Case No. BCV00300. February 13. RATE OF COMPENSATION Mr. Andrews' rate of compensation is $272.00 per hour.