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Brownstown Kilkieran Co Kilkenny Unit 7-8 Hawarden Business Park anor Road (off anor Lane) Hawarden Deeside CH5 3US Tel: (01244) 528700 Fax: (01244) 528701 email: customerservices@alcontrolcom Website: wwwalcontrolcom Date: 14 November 2016 Sample Delivery Group (SDG): D_CGARRY_KIL Your Reference: Report No: We received 7 samples on Friday November 04, 2016 and 7 of these samples were scheduled for analysis which was completed on onday November 14, 2016 Accredited laboratory tests are defined within the report, but opinions, interpretations and on-site data expressed herein are outside the scope of ISO 17025 accreditation Should this report require incorporation into client reports, it must be used in its entirety and not simply with the data sections alone Chemical testing (unless subcontracted) performed at ALcontrol Laboratories Hawarden (ethod codes T) or ALcontrol Laboratories Aberdeen (ethod codes S) Approved By: Sonia cwhan Operations anager Alcontrol Laboratories is a trading division of ALcontrol UK Limited Registered Office: Units 7 & 8 Hawarden Business Park, anor Road, Hawarden, Deeside, CH5 3US Registered in England and Wales No 4057291 Page 1 of 14

Received Sample Overview Lab Sample No(s) AGS Ref Sampled Date 14468502 2510 - BH3 14468501 2504 - GW5 14468506 2506 - GW9 14468500 2507 - GW10 14468507 2509 - GW12 14468505 2511 - LS2 14468503 2513 - LS6 Only received samples which have had analysis scheduled will be shown on the following pages Page 2 of 14

LIQUID Test Lab Sample No(s) 14468502 14468501 14468506 14468500 14468507 14468505 14468503 N No Determination Possible Customer Sample Reference 2510 - BH3 2504 - GW5 2506 - GW9 2507 - GW10 2509 - GW12 2511 - LS2 2513 - LS6 Container Vial (ALE297) NaOH (ALE245) HNO3 Filtered (ALE204) H2SO4 (ALE244) Dissolved etals Preser 1lplastic (ALE221) Vial (ALE297) NaOH (ALE245) HNO3 Filtered (ALE204) H2SO4 (ALE244) Dissolved etals Preser 1lplastic (ALE221) Vial (ALE297) HNO3 Filtered (ALE204) Dissolved etals Preser 1lplastic (ALE221) Vial (ALE297) HNO3 Filtered (ALE204) Dissolved etals Preser 1lplastic (ALE221) Vial (ALE297) HNO3 Filtered (ALE204) Dissolved etals Preser 1lplastic (ALE221) Vial (ALE297) HNO3 Filtered (ALE204) Dissolved etals Preser 1lplastic (ALE221) Vial (ALE297) HNO3 Filtered (ALE204) Dissolved etals Preser 1lplastic (ALE221) Ammoniacal Nitrogen All NDPs: 0 Tests: 2 Anions by Kone (w) All NDPs: 0 Tests: 7 COD Unfiltered All NDPs: 0 Tests: 2 Cyanide Comp/Free/Total/Thiocyanate All NDPs: 0 Tests: 2 Dissolved etals by ICP-S All NDPs: 0 Tests: 7 Fluoride All NDPs: 0 Tests: 2 ercury Dissolved All NDPs: 0 Tests: 7 etals by icap-oes Dissolved (W) All NDPs: 0 Tests: 7 VOC S (W) All NDPs: 0 Tests: 7 Page 3 of 14

ethod 2510 - BH3 14468502 2504 - GW5 14468501 Ammoniacal Nitrogen as N <02 mg/l T099 566 2506 - GW9 14468506 2507 - GW10 14468500 2509 - GW12 14468507 Fluoride <05 mg/l T104 11 COD, unfiltered <7 mg/l T107 754 Boron () <5 µg/l T152 107 176 205 496 353 2040 Cadmium () <008 µg/l T152 0105 <008 <008 <008 <008 <008 Chromium () 2 µg/l T152 2 2 2 2 179 168 Copper () <085 µg/l T152 274 <085 <085 <085 757 237 Lead () <01 µg/l T152 0226 <01 0752 <01 <01 0789 anganese () <076 µg/l T152 169 284 369 <076 275 361 Nickel () <044 µg/l T152 755 131 19 231 128 763 Zinc () 3 µg/l T152 24 164 249 3 291 466 ercury () <001 µg/l T183 <001 <001 <001 <001 <001 <001 Sulphate <2 mg/l T184 0 Chloride <2 mg/l T184 1210 Nitrate as NO3 <03 mg/l T184 498 <03 175 525 257 Phosphate (ortho) as P <002 mg/l T184 <002 <002 <002 <002 <002 017 Total Oxidised Nitrogen as N <01 mg/l T184 <05 Cyanide, Total <005 mg/l T227 <005 Calcium () <0012 mg/l T228 156 Sodium () <0076 mg/l T228 404 agnesium () <0036 mg/l T228 156 Potassium () mg/l T228 115 Iron () <0019 mg/l T228 <0019 134 631 485 0447 169 115 30 184 00887 134 167 113 178 <0019 143 243 853 146 <0019 2511 - LS2 14468505 72 844 122 430 254 Page 4 of 14

ethod 2513 - LS6 14468503 Ammoniacal Nitrogen as N <02 mg/l T099 171 Fluoride <05 mg/l T104 <05 COD, unfiltered <7 mg/l T107 163 Boron () <5 µg/l T152 774 Cadmium () <008 µg/l T152 <008 Chromium () 2 µg/l T152 704 Copper () <085 µg/l T152 <085 Lead () <01 µg/l T152 0147 anganese () <076 µg/l T152 1180 Nickel () <044 µg/l T152 145 Zinc () 3 µg/l T152 366 ercury () <001 µg/l T183 <001 Sulphate <2 mg/l T184 514 Chloride <2 mg/l T184 259 Phosphate (ortho) as P <002 mg/l T184 00414 Total Oxidised Nitrogen as N <01 mg/l T184 0278 Cyanide, Total <005 mg/l T227 <005 Calcium () <0012 mg/l T228 129 Sodium () <0076 mg/l T228 164 agnesium () <0036 mg/l T228 271 Potassium () mg/l T228 751 Iron () <0019 mg/l T228 0349 Page 5 of 14

VOC S (W) ethod 2510 - BH3 14468502 2504 - GW5 14468501 Dibromofluoromethane % T208 121 112 116 117 114 108 2506 - GW9 14468506 2507 - GW10 14468500 2509 - GW12 14468507 Toluene-d8 % T208 989 998 101 995 100 100 2511 - LS2 14468505 4-Bromofluorobenzene % T208 969 99 974 98 975 976 Dichlorodifluoromethane µg/l T208 Chloromethane µg/l T208 Vinyl chloride µg/l T208 Bromomethane µg/l T208 Chloroethane µg/l T208 522 313 Trichlorofluoromethane µg/l T208 1,1-Dichloroethene µg/l T208 Carbon disulphide µg/l T208 Dichloromethane <3 µg/l T208 <3 <3 <3 <3 <3 <3 ethyl tertiary butyl ether µg/l T208 122 (TBE) trans-1,2-dichloroethene µg/l T208 1,1-Dichloroethane µg/l T208 125 397 cis-1,2-dichloroethene µg/l T208 222 2,2-Dichloropropane µg/l T208 Bromochloromethane µg/l T208 Chloroform µg/l T208 1,1,1-Trichloroethane µg/l T208 121 1,1-Dichloropropene µg/l T208 Carbontetrachloride µg/l T208 1,2-Dichloroethane µg/l T208 Benzene µg/l T208 Trichloroethene µg/l T208 1,2-Dichloropropane µg/l T208 Dibromomethane µg/l T208 Bromodichloromethane µg/l T208 cis-1,3-dichloropropene µg/l T208 Toluene µg/l T208 trans-1,3-dichloropropene µg/l T208 1,1,2-Trichloroethane µg/l T208 123 Page 6 of 14

VOC S (W) ethod 2510 - BH3 14468502 2504 - GW5 14468501 2506 - GW9 14468506 2507 - GW10 14468500 2509 - GW12 14468507 1,3-Dichloropropane µg/l T208 Tetrachloroethene µg/l T208 Dibromochloromethane µg/l T208 1,2-Dibromoethane µg/l T208 Chlorobenzene µg/l T208 1,1,1,2-Tetrachloroethane µg/l T208 Ethylbenzene µg/l T208 m,p-ylene µg/l T208 16 o-ylene µg/l T208 265 Styrene µg/l T208 Bromoform µg/l T208 Isopropylbenzene µg/l T208 1,1,2,2-Tetrachloroethane µg/l T208 1,2,3-Trichloropropane µg/l T208 Bromobenzene µg/l T208 Propylbenzene µg/l T208 2-Chlorotoluene µg/l T208 1,3,5-Trimethylbenzene µg/l T208 4-Chlorotoluene µg/l T208 tert-butylbenzene µg/l T208 1,2,4-Trimethylbenzene µg/l T208 103 sec-butylbenzene µg/l T208 4-iso-Propyltoluene µg/l T208 1,3-Dichlorobenzene µg/l T208 1,4-Dichlorobenzene µg/l T208 n-butylbenzene µg/l T208 1,2-Dichlorobenzene µg/l T208 2511 - LS2 14468505 1,2-Dibromo-3-chloropropane µg/l T208 1,2,4-Trichlorobenzene µg/l T208 Hexachlorobutadiene µg/l T208 tert-amyl methyl ether (TAE) µg/l T208 Naphthalene µg/l T208 Page 7 of 14

VOC S (W) ethod 2510 - BH3 14468502 2504 - GW5 14468501 2506 - GW9 14468506 2507 - GW10 14468500 2509 - GW12 14468507 1,2,3-Trichlorobenzene µg/l T208 1,3,5-Trichlorobenzene µg/l T208 2511 - LS2 14468505 Page 8 of 14

VOC S (W) ethod 2513 - LS6 14468503 Dibromofluoromethane % T208 113 Toluene-d8 % T208 996 4-Bromofluorobenzene % T208 972 Dichlorodifluoromethane µg/l T208 Chloromethane µg/l T208 Vinyl chloride µg/l T208 Bromomethane µg/l T208 Chloroethane µg/l T208 Trichlorofluoromethane µg/l T208 1,1-Dichloroethene µg/l T208 Carbon disulphide µg/l T208 Dichloromethane <3 µg/l T208 <3 ethyl tertiary butyl ether (TBE) µg/l T208 177 trans-1,2-dichloroethene µg/l T208 1,1-Dichloroethane µg/l T208 cis-1,2-dichloroethene µg/l T208 2,2-Dichloropropane µg/l T208 Bromochloromethane µg/l T208 Chloroform µg/l T208 1,1,1-Trichloroethane µg/l T208 1,1-Dichloropropene µg/l T208 Carbontetrachloride µg/l T208 1,2-Dichloroethane µg/l T208 Benzene µg/l T208 Trichloroethene µg/l T208 1,2-Dichloropropane µg/l T208 Dibromomethane µg/l T208 Bromodichloromethane µg/l T208 cis-1,3-dichloropropene µg/l T208 Toluene µg/l T208 trans-1,3-dichloropropene µg/l T208 1,1,2-Trichloroethane µg/l T208 Page 9 of 14

VOC S (W) ethod 1,3-Dichloropropane µg/l T208 2513 - LS6 14468503 Tetrachloroethene µg/l T208 Dibromochloromethane µg/l T208 1,2-Dibromoethane µg/l T208 Chlorobenzene µg/l T208 1,1,1,2-Tetrachloroethane µg/l T208 Ethylbenzene µg/l T208 m,p-ylene µg/l T208 o-ylene µg/l T208 Styrene µg/l T208 Bromoform µg/l T208 Isopropylbenzene µg/l T208 1,1,2,2-Tetrachloroethane µg/l T208 1,2,3-Trichloropropane µg/l T208 Bromobenzene µg/l T208 Propylbenzene µg/l T208 2-Chlorotoluene µg/l T208 1,3,5-Trimethylbenzene µg/l T208 4-Chlorotoluene µg/l T208 tert-butylbenzene µg/l T208 1,2,4-Trimethylbenzene µg/l T208 sec-butylbenzene µg/l T208 4-iso-Propyltoluene µg/l T208 1,3-Dichlorobenzene µg/l T208 1,4-Dichlorobenzene µg/l T208 n-butylbenzene µg/l T208 1,2-Dichlorobenzene µg/l T208 1,2-Dibromo-3-chloropropane µg/l T208 1,2,4-Trichlorobenzene µg/l T208 Hexachlorobutadiene µg/l T208 tert-amyl methyl ether (TAE) µg/l T208 Naphthalene µg/l T208 Page 10 of 14

VOC S (W) ethod 2513 - LS6 14468503 1,2,3-Trichlorobenzene µg/l T208 1,3,5-Trichlorobenzene µg/l T208 Page 11 of 14

Table of Results - Appendix ethod No Reference Description T099 BS 2690: Part 7:1968 / BS 6068: Part211:1984 Determination of Ammonium in Water Samples using the Kone Analyser T104 ethod 4500F, AWWA/APHA, 20th Ed, 1999 Determination of Fluoride using the Kone Analyser T107 ISO 6060-1989 Determination of Chemical Oxygen Demand using COD Dr Lange Kit T152 ethod 3125B, AWWA/APHA, 20th Ed, 1999 Analysis of Aqueous Samples by ICP-S T183 BS EN 23506:2002, (BS 6068-274:2002) ISBN 0 580 38924 3 Determination of Trace Level ercury in Waters and Leachates by PSA Cold Vapour Atomic Fluorescence Spectrometry T184 EPA ethods 3251 & 3252, The Determination of Anions in Aqueous atrices using the Kone Spectrophotometric Analysers T208 odified: US EPA ethod 8260b & 624 Determination of Volatile Organic Compounds by Headspace / GC-S in Waters T227 Standard methods for the examination of waters and wastewaters 20th Edition, AWWA/APHA ethod 4500 Determination of Total Cyanide, Free (Easily Liberatable) Cyanide and Thiocyanate T228 US EPA ethod 6010B Determination of ajor Cations in Water by icap 6500 Duo ICP-OES ¹ Applies to Solid samples only DRY indicates samples have been dried at 35 C NA = not applicable Chemical testing (unless subcontracted) performed at ALcontrol Laboratories Hawarden (ethod codes T) or ALcontrol Laboratories Aberdeen (ethod codes S) Wet/Dry Sample ¹ Surrogate Corrected Page 12 of 14

Lab Sample No(s) Test Completion Dates 14468502 14468501 14468506 14468500 14468507 14468505 14468503 2510 - BH3 2504 - GW5 2506 - GW9 2507 - GW10 2509 - GW12 2511 - LS2 2513 - LS6 AGS Ref Depth Type LIQUID LIQUID LIQUID LIQUID LIQUID LIQUID LIQUID Ammoniacal Nitrogen 12-Nov-2016 11-Nov-2016 Anions by Kone (w) 14-Nov-2016 14-Nov-2016 14-Nov-2016 14-Nov-2016 14-Nov-2016 12-Nov-2016 12-Nov-2016 COD Unfiltered 11-Nov-2016 11-Nov-2016 Cyanide Comp/Free/Total/Thiocyanate 11-Nov-2016 11-Nov-2016 Dissolved etals by ICP-S 14-Nov-2016 14-Nov-2016 14-Nov-2016 14-Nov-2016 14-Nov-2016 14-Nov-2016 14-Nov-2016 Fluoride 14-Nov-2016 14-Nov-2016 ercury Dissolved 14-Nov-2016 14-Nov-2016 14-Nov-2016 14-Nov-2016 14-Nov-2016 14-Nov-2016 14-Nov-2016 etals by icap-oes Dissolved (W) 11-Nov-2016 11-Nov-2016 11-Nov-2016 11-Nov-2016 11-Nov-2016 14-Nov-2016 11-Nov-2016 Nitrite by Kone (w) 12-Nov-2016 12-Nov-2016 12-Nov-2016 12-Nov-2016 12-Nov-2016 VOC S (W) 10-Nov-2016 10-Nov-2016 10-Nov-2016 10-Nov-2016 10-Nov-2016 10-Nov-2016 10-Nov-2016 Page 13 of 14

Appendix 1 Results are expressed on a dry weight basis (dried at 35ºC) for all soil analyses except for the following: NRA and CEN Leach tests, flash point LOI, ph, ammonium as NH4 by the BRE method, VOC TICs and SVOC TICs 2 Samples will be run in duplicate upon request, but an additional charge may be incurred 3 If sufficient sample is received a sub sample will be retained free of charge for 30 days after analysis is completed (e-mailed) for all sample types unless the sample is destroyed on testing The prepared soil sub sample that is analysed for asbestos will be retained for a period of 6 months after the analysis date All bulk samples will be retained for a period of 6 months after the analysis date All samples received and not scheduled will be disposed of one month after the date of receipt unless we are instructed to the contrary Once the initial period has expired, a storage charge will be applied for each month or part thereof until the client cancels the request for sample storage ALcontrol Laboratories reserve the right to charge for samples received and stored but not analysed 4 With respect to turnaround, we will always endeavour to meet client requirements wherever possible, but turnaround times cannot be absolutely guaranteed due to so many variables beyond our control 5 We take responsibility for any test performed by sub-contractors (marked with an asterisk) We endeavour to use UKAS/CERTS Accredited Laboratories, who either complete a quality questionnaire or are audited by ourselves For some determinands there are no UKAS/CERTS Accredited Laboratories, in this instance a laboratory with a known track record will be utilised 6 When requested, the individual sub sample scheduled will be analysed in house for the presence of asbestos fibres and asbestos containing material by our documented in house method T048 based on HSG 248 (2005), which is accredited to ISO17025 If a specific asbestos fibre type is not found this will be reported as Not detected If no asbestos fibre types are found all will be reported as Not detected and the sub sample analysed deemed to be clear of asbestos If an asbestos fibre type is found it will be reported as detected (for each fibre type found) Testing can be carried out on asbestos positive samples, but, due to Health and Safety considerations, may be replaced by alternative tests or reported as No Determination Possible (NDP) The quantity of asbestos present is not determined unless specifically requested 7 If no separate volatile sample is supplied by the client, or if a headspace or sediment is present in the volatile sample, the integrity of the data may be compromised This will be flagged up as an invalid VOC on the test schedule and the result marked as deviating on the test certificate 8 If appropriate preserved bottles are not received preservation will take place on receipt However, the integrity of the data may be compromised 9 NDP - No determination possible due to insufficient/unsuitable sample 10 etals in water are performed on a filtered sample, and therefore represent dissolved metals - total metals must be requested separately 11 Results relate only to the items tested 12 LoDs (Limit of Detection) for wet tests reported on a dry weight basis are not corrected for moisture content General Identification of Asbestos in Bulk aterials & Soils 20 For the BSEN 12457-3 two batch process to allow the cumulative release to be calculated, the volume of the leachate produced is measured and filtered for all tests We therefore cannot carry out any unfiltered analysis The tests affected include volatiles GCFID/GCS and all subcontracted analysis 21 For leachate preparations other than Zero Headspace Extraction (ZHE) volatile loss may occur 22 We are accredited to CERTS for sand, clay and loam/topsoil, or any of these materials - whether these are derived from naturally occurring soil profiles, or from fill /made ground, as long as these materials constitute the major part of the sample Other coarse granular material such as concrete, gravel and brick are not accredited if they comprise the major part of the sample 23 Analysis and identification of specific compounds using GCFID is by retention time only, and we routinely calibrate and quantify for benzene, toluene, ethylbenzenes and xylenes (BTE) For total volatiles in the C5-C12 range, the total area of the chromatogram is integrated and expressed as ug/kg or ug/l Although this analysis is commonly used for the quantification of gasoline range organics (GRO), the system will also detect other compounds such as chlorinated solvents, and this may lead to a falsely high result with respect to hydrocarbons only It is not possible to specifically identify these non-hydrocarbons, as standards are not routinely run for any other compounds, and for more definitive identification, volatiles by GCS should be utilised 24 Tentatively Identified Compounds (TICs) are non-target peaks in VOC and SVOC analysis All non-target peaks detected with a concentration above the LoD are subjected to a mass spectral library search Non-target peaks with a library search confidence of >75% are reported based on the best mass spectral library match When a non-target peak with a library search confidence of <75% is detected it is reported as mixed hydrocarbons Non-target compounds identified from the scan data are semi-quantified relative to one of the deuterated internal standards, under the same chromatographic conditions as the target compounds This result is reported as a semi-quantitative value and reported as Tentatively Identified Compounds (TICs) TICs are outside the scope of UKAS accreditation and are not moisture corrected Sample Deviations 1 2 3 4 5 @ & Container with Headspace provided for volatiles analysis Incorrect container received Deviation from method Holding time exceeded before sample received Samples exceeded holding time before presevation was performed Sampled on date not provided Sample holding time exceeded in laboratory Sample holding time exceeded due to sampled on date Sample Holding Time exceeded - Late arrival of instructions Asbestos The results for identification of asbestos in bulk materials are obtained from supplied bulk materials which have been examined to determine the presence of asbestos fibres using ALcontrol Laboratories (Hawarden) in-house method of transmitted/polarised light microscopy and central stop dispersion staining, based on HSG 248 (2005) 13 Surrogate recoveries - Surrogates are added to your sample to monitor recovery of the test requested A % recovery is reported, results are not corrected for the recovery measured Typical recoveries for organics tests are 70-130%, they are generally wider for volatiles analysis, 50-150% Recoveries in soils are affected by organic rich or clay rich matrices Waters can be affected by remediation fluids or high amounts of sediment Test results are only ever reported if all of the associated quality checks pass; it is assumed that all recoveries outside of the values above are due to matrix affect The results for identification of asbestos in soils are obtained from a homogenised sub sample which has been examined to determine the presence of asbestos fibres using ALcontrol Laboratories (Hawarden) in-house method of transmitted/polarised light microscopy and central stop dispersion staining, based on HSG 248 (2005) Asbestos Type Common Name 14 Product analyses - Organic analyses on products can only be semi-quantitative due to the matrix effects and high dilution factors employed Chrysotile Amosite Crocidolite White Asbestos Brown Asbestos Blue Asbestos 15 Phenols monohydric by HPLC include phenol, cresols (2-ethylphenol, 3-ethylphenol and 4-ethylphenol) and ylenols (2,3 Dimethylphenol, 2,4 Dimethylphenol, 2,5 Dimethylphenol, 2,6 Dimethylphenol, 3,4 Dimethyphenol, 3,5 Dimethylphenol) 16 Total of 5 speciated phenols by HPLC includes Phenol, 2,3,5-Trimethyl Phenol, 2-Isopropylphenol, Cresols and ylenols (as detailed in 15) 17 Stones/debris are not routinely removed We always endeavour to take a representative sub sample from the received sample 18 In certain circumstances the method detection limit may be elevated due to the sample being outside the calibration range Other factors that may contribute to this include possible interferences In both cases the sample would be diluted which would cause the method detection limit to be raised 19 ercury results quoted on soils will not include volatile mercury as the analysis is performed on a dried and crushed sample Visual Estimation Of Fibre Content Fibrous Actinolite Fibrous Anthophyllite Fibrous Tremolite Estimation of fibre content is not permitted as part of our UKAS accredited test other than : - Trace - Where only one or two asbestos fibres were identified Further guidance on typical asbestos fibre content of manufactured products can be found in HSG 264 The identification of asbestos containing materials and soils falls within our schedule of tests for which we hold UKAS accreditation, however opinions, interpretations and all other information contained in the report are outside the scope of UKAS accreditation - - - 16:42:41 14/11/2016 odification Date: 14/11/2016 Page 14 of 14

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