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Use of Multi-Media Monitoring to Develop a Statewide Mercury TMDL Bruce Monson and Howard Markus Environmental Analysis & Outcomes Division Minnesota Pollution.

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Presentation on theme: "Use of Multi-Media Monitoring to Develop a Statewide Mercury TMDL Bruce Monson and Howard Markus Environmental Analysis & Outcomes Division Minnesota Pollution."— Presentation transcript:

1 Use of Multi-Media Monitoring to Develop a Statewide Mercury TMDL Bruce Monson and Howard Markus Environmental Analysis & Outcomes Division Minnesota Pollution Control Agency

2 2 Minnesota’s Impaired Waters 2004

3 3 Waters Impaired by Mercury in Fish FCA more restrictive than 1 meal/wk for moms & kids (>0.2 ppm for a fish size class)

4 4 Minnesota Mercury TMDL Regions TMDL REGION Dominant Mercury Transport Process Northeast (NE) Forest & wetland hydrology Southwest (SW) Erosion from cultivated land

5 5 Target Level & Reduction Factor NESW Target fish mercury concentration 0.2 mg/kg 0.2 mg/kg Mercury concentration for standard length walleye (WE40 90 ) 0.572 mg/kg 0.405 mg/kg Reduction Factor (RF) = (WE40 90 – 0.2)  WE40 90 ) 65%51% Anthropogenic RF = (WE40 90 – 0.2)  WE40 90 )  70% 93%73%

6 6 90 % from emission sources outside Minnesota How do we know? Mercury Deposition to Minnesota Lakes 10 % from emission sources within Minnesota

7 7 Total Mercury Deposition is Based on Sediment Cores Engstrom and Swain collecting a sediment core

8 8 Swain, Engstrom, Brigham, Henning, and Brezonik. 1992. Science 257, 784-787

9 9 Sources of Atmospheric Mercury Deposition in North-Central US (Engstrom and Swain 1997 ES&T) 2X 3X 4X 1700175018001850190019502000 Year Regional North America Natural mercury deposition Global (Coastal Alaska) Natural 30% Global 30% Regional 40%

10 10 Atmospheric Deposition: Sediment Core Findings ~70% current Hg deposition in MN from anthropogenic emissions (30% global + 40% regional) Annual atmospheric deposition ~ 12.5 µg/m2 Atm Dep peaked ~1970s in some parts of MN Deposition now relatively uniform across state; no known fish tissue hot spots

11 11 Purposeful Use 28% Sources of Minnesota’s Mercury Deposition Minnesota Mercury Emissions (2000) Coal 46% Petroleum 5% Wood 0.3% Natural gas 0.0% Volatilization from disposed products 7% Municipal solid waste combustion 5% Smelters that recycle cars and appliances 5% Sewage sludge incineration 3% Dental preparations 3% Crematories 2% On-site household waste incineration 2% Recycling mercury from products 1.4% Fluorescent lamp breakage 0.9% Medical waste incineration 0.2% Taconite processing 21% Soil roasting 0.4% Energy 51% Material Processing 21% Sources of Atmospheric Mercury Deposition to Minnesota Natural Emissions 30% Global Emissions 30% Regional Emissions 40% MN Emissions (~10%) Source: Minnesota Pollution Control Agency March 2004

12 12 Minnesota Mercury Emissions, 1990, 1995, 2000 and Projected 2005

13 13 Mercury Deposition Network

14 14 Annual Wet Deposition at MN Sites

15 15 DNR Fish Collection DNR Fish Processing DNR/MDA Chemical Analysis DNR Data Reporting MDH Public Health Evaluation MPCA DNR MDH Site Selection MPCA Analysis & Research Fish Contaminant Monitoring Process

16 16 Minnesota’s Fish Consumption Advisory Levels Applied to Fish Size Classes Population 0.2

17 17 Sand Point Lake 69-617 Northern Pike, 1997 Fish Length, cm Mercury Concentration (mg/kg) 4050607080 0.2 0.4 0.6 0.8 2 Calculating Standard Concentration of Northern Pike

18 18 Water Point Sources of Mercury – Existing, Expanding, & New Data from about 37 facilities, averaged 5 ng/L Hg WLA not to exceed 1% of total mercury load allocation [11 kg/yr] In 1990, water point sources about 1.2% of total New & expanding water sources can expand up to the current WLA of 11 kg/yr Mercury minimization plan required

19 19 Summary of Monitoring Data Needed to Prepare the Statewide Mercury TMDL Fish tissue mercury data to show spatial differences and includes data from 1988–1992 Sediment core data sufficient to est. whole basin mercury fluxes Wet deposition stations across the state to show uniform deposition Wastewater effluent data to estimate WLA

20 20 Future TMDL Monitoring Needs Fish tissue trends Dry deposition (as well as Wet Dep) Follow up intensive lake sediment core study Wasteload allocation studies (upstream/downstream)

21 21 Questions? Bruce Monson Minnesota Pollution Control Agency 651-296-7605 bruce.monson@state.mn.us

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