Petroleum Hydrocarbon Sediment Quality Guidelines

Transcription

1 Petroleum Hydrocarbon Sediment Quality Guidelines Rita Mroz, Environment Canada Ulysses Klee, Stantec Rob Willis, Dillon Consulting Real Property Institute of Canada Federal Contaminated Sites National Workshop Montreal, April 2016

2 Total Petroleum Hydrocarbon (TPH) Sediment Criteria Developed by Atlantic PIRI Released in 2012 Today s presentation: How the values were derived Sediment toxicity testing for validation Laboratory/analytical considerations

3 Background Atlantic PIRI = Atlantic Partners In RBCA Implementation RBCA = Risk Based Corrective Action (ASTM) Established in 1997, it is a partnership between Regulators, Industry and Consultants Formal MOU between 4 Atlantic Provinces; promotes harmonization in the assessment and remediation of petroleum hydrocarbon contaminated sites Atlantic PIRI is responsible for Atlantic RBCA implementation and continuous improvement

4 Background Heavy fuel oil demand Source: StatsCan, CANSIM tables and The Atlantic Region uses more fuel oil than other regions in Canada (electricity generation, home heating, etc). As a result of spills, leaks, etc, provinces and industry were motivated to develop risk-based harmonized remediation criteria

5 Background Canada Wide Standards for Petroleum Hydrocarbons in Soil Issued in 2000; updated 2008 Provides soil screening criteria for human health and ecological receptors Criteria provided as fractions (F1-F4) Atlantic RBCA Issued in 1998; updated 2003 and 2012 Provides soil and groundwater screening criteria for human health and soil, groundwater, surface water and sediment screening criteria for ecological receptors Criteria provided as products (gas, diesel and lube oil)

6 Atlantic RBCA Version 1 (1998) and Version 2 (2003) provided human health based criteria only Ecological considerations Identification of potential ecological concerns addressed via a one page screening form Questions focused on habitat presence/absence Atlantic PIRI wanted to expand the eco assessment to include eco-based screening criteria for soil, groundwater, surface water and sediment.

7 EcoTask Group Formed in 2006 Members: Ken Doe, Environment Canada Ulysses Klee, Stantec (formerly Dillon) Peter Miasek, Imperial Oil Rita Mroz, Environment Canada Malcolm Stephenson, Stantec Rob Willis, Dillon (formerly Intrinsik) Affiliate members: Chris Allaway, EC (Ottawa) and Thomas Parkerton, Exxon Mobil Purpose: Update/revise eco-screening checklist in RBCA User Guidance Improve guidance Include eco-based criteria for soil, sediment, surface water and ground water

8 Eco Screening Levels Soil adopted from CWS, 2008 Groundwater to surface water PETROTOX Shallow groundwater (direct contact) Alberta Environment Surface Water PETROTOX Sediment PETROTOX & Equilibrium Partitioning model

9 Surface water-sediment Link Sediment criteria based on the surface water criteria Next slides explain derivation of surface water eco screening levels, then sediment

10 Surface Water Eco Screening Levels Protection of aquatic life (plants, fish, invertebrates) CCME does not have surface water criteria for PHCs CCME does have surface water criteria for benzene, toluene and ethyl benzene but not xylene (late 1990 s) Task Group considered options to derive both BTEX and PHCs screening values selected PETROTOX Derived surface water screening criteria for BTEX, gasoline, diesel and lube using PETROTOX Surface water screening criteria sediment criteria, by applying the equilibrium partitioning model (EqP)

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12 Sediment Eco Screening Levels Protection of aquatic life (plants, fish, invertebrates) Equilibrium partitioning model (EqP) Assumes toxicity of a chemical in sediment is the result of chemical concentration in the aqueous phase Partitioning behaviour of an organic is a function of the chemical s organic carbon-water partitioning coefficient (K oc ) and the sediment s fraction organic carbon (F oc ) Sediment ESL = surface water ESL x K oc x F oc Allows for adjustments based on F oc site-specific F oc (Atlantic RBCA eco screening levels assume default F oc of 0.01) Maximum of 500 mg/kg TPH ( management limit )

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14 Two sediment categories Typical : where sediment is used to support sensitive components of aquatic ecosystems (e.g. fish spawning, intertidal zones that are important for the preservation of fish & wildlife, etc.) Other : for sediments not classified as typical (e.g. ditches, industrial- influenced receiving areas, etc.) FCSAP advises to screen against typical screening levels; site professional must provide sufficient rationale for applying other

15 Sediment Toxicity Tests # 2 Oil (Winter Diesel) and # 6 Oil (Bunker C) Hyalella azteca (amphipod) and Chironomus dilutus (midge) EC methods Artificial Sediment Static and static/renewal

16 LC50 (mg/kg) H. azteca - S PetroTox Results - #6 Oil EC50 (mg/kg) H. azteca - S Petrotox 200 0

17 Sediment Toxicity Testing 2015 Real sediment Sediment from known PHC contaminated FCSAP site Marine amphipod, Eohaustorius estuarius Survival, emergence and re-burial F oc determined = 0.04 Product = #6 fuel

18 Results % survival % survival (E. estuarius) Sites TPH concentration TPH concentration -- Atlantic PIRI eco screening level, adjusted for F oc of 0.04 (43 mg/kg x 4 = 172 mg/kg for #6 oil/lube)

19 Analytical Considerations for Using PIRI ESLs at Federal Sites Concentrations of PHCs at federal sites most often reported as CWS fractions (F1-F4). Atlantic PIRI criteria are provided as modified TPH for 3 specific products (gas, diesel and lube). How to use CWS data with Atlantic PIRI criteria?

20 Step 1: Calculate a modified TPH value Add F1+ F2 + F3 (less BTEX) data to calculate a Modified TPH concentration value Atlantic PIRI criteria includes up to C32 while CCME F3 reports to C34. Not likely to be an issue - uncertainty in 2 carbon units much less than the uncertainty due to overall sample homogeneity and analysis methodologies. Note: Atlantic PIRI did not derive criteria for products in F4 range (C34-C50). F4 should not be included in the summation for the Modified TPH value. If sediment has concentrations in F4 range, alternate methods of screening required.

21 Comparison Study (Feb 2016)

22 Conclusions of Comparison Study Methods are comparable Despite the difference between analyzing >C32 vs C34, results are similar General trend that CWS TPH is lower than PIRI TPH could be due to the silica gel clean-up required in CWS method (reduce the overall TPH value by removing non-petrogenic compounds) Overall, adding CWS F1+ F2+ F3 is a valid recommendation to generate a modified TPH value Special thank you to A. Stewart, R. Whelan, and B. Loescher, Maxxam Analytics (Bedford/St John s) for undertaking this study

23 Step 2: Product Type To select the appropriate modified TPH criteria, product type must be determined Gas? Diesel? Lube? Can be done by: Site history Laboratory resemblance comments (CCME Reference Method, 2001; Atlantic PIRI Guidelines for Laboratories, 2016)

24 Step 3 Compare to Appropriate Eco Screening Level Example: Sum of F1-F3 is 45 mg/kg, resembles diesel.

25 If Fraction of Organic Carbon is known. Sum of F1-F3 is 45 mg/kg, resembles diesel, with an F oc of 0.02 (2%) Screening level is multiplied by 2 to become 50 mg/kg (as default ESLs assume F oc is 0.01.if 0.02, than criteria is doubled, so long as to remain below 500 mg/kg) x 2

26 Atlantic PIRI website: (User Guidance, Scientific Rationale Document)

27 Questions?

28 PETROTOX Model Developed by CONCAWE (Conservation of Clean Air and Water in Europe) Regulatory Developments: REACH legislation in EU Requirement for conducting environmental risk assessments for petroleum substances New initiatives aimed at avoiding / reducing animal toxicity testing In Canada: Used by EC/HC for screening assessments for petroleum products as part of the Chemical Management Plan

29 PETROTOX Model Calculates toxicity of petroleum products to aquatic organisms Based on quantitative relationships between hydrocarbon structure and eco-toxicity (QSAR model) Applies target lipid narcosis model Toxicity database for 42 aquatic species (fish, amphibians, invertebrates and algae) and 1457 hydrocarbons Phys-chem property database for PHCs Assumes hydrocarbon toxicity is additive Estimates predicted-no-effect-concentration (PNECs) for aquatic species exposed to PHCs (including BTEX, gasoline, diesel, lube oil) based on HC5 (5 th percentile) of species sensitivity distributions