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(Total and) Methyl Mercury Export from Denitrifying Bioreactors in Tile-Drained Fields of Central Illinois

(Total and) Methyl Mercury Export from Denitrifying Bioreactors in Tile-Drained Fields of Central Illinois. Robert J.M. Hudson, NRES Richard A.C. Cooke, ABE University of Illinois at Urbana-Champaign. Acknowledgements. Illinois Sustainable Technology Center Funding for the project

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(Total and) Methyl Mercury Export from Denitrifying Bioreactors in Tile-Drained Fields of Central Illinois

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  1. (Total and)Methyl Mercury Export from Denitrifying Bioreactors in Tile-Drained Fields of Central Illinois Robert J.M. Hudson, NRES Richard A.C. Cooke, ABE University of Illinois at Urbana-Champaign

  2. Acknowledgements • Illinois Sustainable Technology Center • Funding for the project • Patience with our pace • Brian Vermillion (foremerly NRES) • MeHg analysis • Richard Cooke group • Access to field sites and assistance with sampling • Expertise

  3. A Tale of Two Elements Both have complex biogeochemical cycles involving chemical species in multiple phases and oxidation states: Nitrogen N2(g) , NO3-(aq), NH4+(aq), Soil Organic N, etc. Mercury Hg(g) , Hg2+(aq), CH3Hg+(aq), HgS(s), etc. A Tale of Two Elements

  4. Pollutant Sources and Impacts Nitrogen • Non-point source pollutant derived from fertilizer overuse • Nitrate exported from agricultural fields impacts: • Gulf of Mexico ecosystem (hypoxia) • Water quality for communities that obtain drinking water from rivers in agricultural areas Mercury • Non-point source pollutant generated via coal combustion and waste incineration • Methylmercury strongly bioaccumulates in food webs: • Fish consumption is main source of human exposure to Hg. • Leading cause of freshwater fish consumption advisories in the U.S. • Significant percentage of U.S. women of childbearing age have blood Hg higher than the USEPA “Threshold Level”. A Tale of Two Elements

  5. Anaerobic Processing Key processes that determine the environmental impacts of each element occur in anaerobic environments: Denitrification (alleviates impacts) NO3-(aq) NO2-(aq) N2(g) Mercury methylation (greatly increases impacts) Hg2+(aq) CH3Hg+(aq) A Tale of Two Elements

  6. HgII HgII Anaerobic Transformations in Aquatic Ecosystems Photosynthesis NO3- O2 Plants A Tale of Two Elements Respiration Trophic Transfer MeHg O2 NO3-MnO2(s) FeOx (s) SO42- H2O N2Mn2+ Fe2+ H2S Sediments &Hyporheic Oxidation Reduction Hg(SH)2 SRB Methylation MeHg Groundwater Nitrate in surface waters inhibits Hg methylation since denitrifiers can out compete Fe- and Sulfate-reducing bacteria for energy (reduced carbon compounds).

  7. Methylation Theoretical Considerations Bioavailability of HgII in Natural Ecosystems RSH + Hg(OH)2 + 2 H+RS-Hg (unavailble) H2S + RS-Hg  Hg(SH)2 Sulfate-reducing bacteria control this reaction by producing H2S. SRB also have the right enzymes to methylate. Fe reducers do as well, but may depend on SRB to make HgII bioavailable.

  8. Clear Pond, Kickapoo State Park Profile (August 2010) MeHg Analysis at UIUC by W.Y. Chen

  9. Landscape-Scale Effects of Natural Anaerobic Ecosystems on Mercury Cycling Brigham et al. (2009)

  10. Constructed Anaerobic Ecosystems

  11. Denitrifying Bioreactors: Constructed Anaerobic Ecosystems • Pioneered by Richard Cooke, ABE-UIUC. • Designed to reduce nitrate export from tile-drained fields. • Economical • Small footprint • Wood chips are inexpensive • Minimal cost of water control structures (<$10k) • Little time required to operate/maintain • Field tests show their high efficiency at NO3- removal. Denitrifying Bioreactors

  12. Monticello Bioreactor Site Denitrifying Bioreactors

  13. Denitrifying Bioreactors

  14. Diversion Structure Second Generation Bioreactors Capacity Control Structure Denitrifying Bioreactors Woodchips

  15. Denitrifying Bioreactors Andrus et al. (2010)

  16. 5’ Soil backfill 10’ Wide Top View Denitrifying Bioreactors 5’ section of non-perforated tile Diversion structure Capacity control structure Length dependent on treatment area Up to soil surface Side View Trench bottom 1’ below tile invert

  17. Denitrifying Bioreactors

  18. Biogeochemistry Denitrifying Bioreactors Abrus et al.

  19. Bioreactor MethylmercuryStudy Objective • Determine whether denitrifying bioreactors produce methylmercury due to anoxic environments formed within bioreactor. • Determine total Hg export flux. • Compare to natural levels in environment.

  20. Bioreactor MethylmercuryStudy Design • Synoptic sampling design • Collect samples after storm events and other periods when tiles are flowing • Inlet and outlet sampled simultaneously • Sampled periodically from summer 2008-June 2009 • Sampled again in summer 2010. • Preserved by filtration/acidification or freezing. • Analyze • Dissolved Methylmercury (MeHg) • Dissolved organic carbon • Sulfate, nitrate, chloride • Only a limited number of samples have been analyzed to date.

  21. Sampling Bioreactors Inlet Samples Outlet Samples

  22. UIUC Method for Hg Speciation Analysis • Shade and Hudson (2005) Environmental Science and Technology • Shade, Hudson, et al. patent (circa 2007) • Vermillion and Hudson (2007). Analytical and Bioanalytical Chemistry. Preparation method for water samples.

  23. pH-Modulated Thiol-Thione Switch After Laws (1970) Thiol Resin -S-H -S-H -S-H + + pH<2: Desorption Favored H+ Thiol Resin -S-H H pH > 3: Adsorption Favored + -S- H -S-H University of Illinois at Urbana-Champaign

  24. Thiourea Complexes of Hg2+ and CH3Hg+ + MeHg+ Hg2+ 2+ University of Illinois at Urbana-Champaign

  25. Mercury-thiourea complex ion chromatography Shade and Hudson, ES&T 2005 University of Illinois at Urbana-Champaign

  26. Dissolved methylmercury: Thiourea-catalyzedsolid phase extraction Vermillion and Hudson Analytical and Bioanalytical Chemistry (2007) Brian Vermillion University of Illinois at Urbana-Champaign

  27. Validation of Sediment and Biota Sample Preparations • Biota: Leaching of tissues in acidic TU (Shade, ES&T 2008) • Sediments: H2SO4+KBr Digestion/Toluene Extraction(Vermillion, Shade, and Hudson, in prep)

  28. Comparison of Methods for Analysis of Dissolved MeHg Gas Chromatography _____________ Ion Chromatography AFS _________ AFS Distillation ________ TU-Catalyzed SPE Ethylation/Purge & Trap __________ Elute SPE/Online Trap University of Illinois at Urbana-Champaign

  29. Intercomparison with Distillation/Ethylation ICP-MS Trent University (Hintelmann)

  30. Intercomparison with USGS Wisconsin District Mercury Lab (Krabbenhoft)

  31. Bioreactor Study Results

  32. Dissolved MeHg in Bioreactor Inlets -Eight non-detects -Six samples contained detectable MeHg - Maximum: 0.16 ng/L - Average: 0.09 ng/L

  33. Dissolved MeHg in Bioreactor Outlets

  34. Farm Progress City Bioreactor

  35. Nitrate Removal

  36. “Typical” Hg Levels • Groundwater • Total Hg is very low (<0.5 ng/L) • MeHg is often non-detectable. • Surface Waters • Total Hg is usually 1-5 ng/L in unpolluted systems • MeHg is usually <0.5 ng/L in unpolluted systems

  37. Possible Relationship between Methylmercury Production to Sulfate Consumption in Bioreactors

  38. Dissolved Organic Carbon • Dissolved organic carbon is known to be a carrier of mercury and methylmercury. • DOC in inlets: • Geometric mean of 1.6 mg-C/L • DOC in outlets: • Geometric mean of 16 mg-C/L • Exhibits seasonality

  39. Summary of Results to Date • Levels in bioreactor discharge are much higher than in tile drain water entering bioreactors. • Methylmercury is clearly produced in bioreactors. • Some combination of increase in DOC and decrease in sulfate may be responsible. • Levels in bioreactor discharge are much higher than typical surface water values (0.1-0.3 ng/L).

  40. What is source of Hg? • Tile water: • Groundwater is typically very low except when preferential flow occurs • Could accumulate on wood chips during high flow (aerobic conditions) and be released under high flow conditions • Wood chips: • Trees accumulate Hg from air and soil water in the wood

  41. Methylation Theoretical Considerations Bioavailability of HgII in Natural Ecosystems RSH + Hg(OH)2 + 2 H+RS-Hg (unavailble) H2S + RS-Hg  Hg(SH)2 Sulfate-reducing bacteria control this reaction by producing H2S. SRB also have the right enzymes to methylate. Fe reducers do as well, but may depend on SRB to make HgII bioavailable.

  42. Questions What controls the extent of methylation? • Amount of sulfate in tile drainage? • Extent of anoxia? • Flow rate? Can reactors be designed to minimize MeHg formation?

  43. 5’ Soil backfill 10’ Wide Top View Denitrifying Bioreactors 5’ section of non-perforated tile Diversion structure Capacity control structure Length dependent on treatment area Up to soil surface Side View Trench bottom 1’ below tile invert Trench bottom at tile invert

  44. Implications • MeHg is produced in some bioreactors. • Effect on MeHg fluxes in watersheds needs to be considered • An apparent trade-off: • Reducing nitrate levels to make water drinkable may make the waters downstream unfishable.

  45. Implications (cont.) • Reduction of MeHg production likely can be attained by adjusting design: • Eliminate ponding zones • Use of low-Hg wood (hypothesis)

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