Science Assessment to Support an Illinois Nutrient Reduction Strategy Mark David, George Czapar, Greg McIsaac, Corey Mitchell August 8, 2013 11-08-12.

Slides:

Advertisements

Similar presentations

Overview – Nutrient Fate and Transport Mark B. David University of Illinois at Urbana-Champaign Presented at Building Science Assessments for State-Level.

Advertisements

RTI International RTI International is a trade name of Research Triangle Institute. Economic Study of Nutrient Credit Trading for the Chesapeake.

Truckee River Water Quality: Current Conditions and Trends Relevant to TMDLs and WLAs Prepared for: Truckee Meadows Water Reclamation Facility. City of.

1 Europe’s water – an indicator-based assessment Niels Thyssen.

©2003 Institute of Water Research, all rights reserved Water Quality Modeling for Ecological Services under Cropping and Grazing Systems Da Ouyang Jon.

Effects of Conservation Tillage Systems on Dissolved Phosphorus Dr. David Baker Heidelberg University Tiffin, Ohio November 15, 2012 Davenport, IA.

U.S. Department of the Interior U.S. Geological Survey Welcome to the USGS Webinar: New Science and Online Management Tools to Help Guide Action on Nutrients.

Agricultural Phosphorus and Eutrophication by Don Pitts Agricultural Engineer & Water Quality Specialist USDA, NRCS Champaign, IL.

Scenario Analysis costs per acre for various practices estimate each fully applied practice for N or P then combine for N or P to reach 20 or 45% finally,

Team Meeting #5, Great Lakes Protection Fund Grant A Phosphorus Soil Test Metric To Reduce Dissolved Phosphorus Loading to Lake Erie Heidelberg University.

Developing Modeling Tools in Support of Nutrient Reduction Policies Randy Mentz Adam Freihoefer, Trip Hook, & Theresa Nelson Water Quality Modeling Technical.

Defining Land Management in the Wisconsin River Basin Defining Land Management in the Wisconsin River Basin Adam Freihoefer Wisconsin Department of Natural.

Minnesota Watershed Nitrogen Reduction Planning Tool William Lazarus Department of Applied Economics University of Minnesota David Mulla Department of.

SOURCES AND FLUX OF NUTRIENTS IN THE MISSISSIPPI RIVER BASIN: MONITORING, MODELING, & RESEARCH NEEDS Donald A. Goolsby, U.S. Geological Survey.

Illinois Drought Response Task Force Arlan Juhl, Director of the Illinois Department of Natural Resources.

Water Quality Concerns in Ohio Waters What has been Happening in Lake Erie? Greg LaBarge, Field Specialist, Agronomic Systems.

DRAINAGE WATER MANAGEMENT FOR MIDWESTERN ROW CROP AGRICULTURE DWM PARTNER FORUM II JUNE 15, 2011 WAYNE HONEYCUTT USDA-NRCS.

Soil Properties and Behaviour

CENTRAL MISSISSIPPI RIVER BASIN (CMRB) LTAR USDA-ARS Columbia Missouri Translating Missouri USDA-ARS Research and Technology into Practice A training session.

Science Assessment to Support an Illinois Nutrient Loss Reduction Strategy Mark David, Greg McIsaac, George Czapar, Gary Schnitkey, Corey Mitchell University.

SPARROW Modeling in the Mississippi River Basin Iowa Science Assessment Davenport, IA Nov. 14, 2012 (608) By Dale M. Robertson*

A FRAMEWORK FOR ASSESSING THE PERFORMANCE OF DWM AT LARGE SCALE MOHAMED A. YOUSSEF and R. WAYNE SKAGGS 1 By.

Nutrient Trading Framework in the Coosa Basin April 22, 2015.

Illinois Farmers as Nutrient Stewards: Opportunities via the Illinois Nutrient Loss Reduction Strategy IFB Commodities Conference July 30, 2014 Lauren.

Laboratory Analysis: Samples were analyzed for: Dissolved Organic Nitrogen (DON) Dissolved Inorganic Nitrogen (NH 4 and NO 3 ) Total Dissolved Nitrogen.

Eric G. Hurley, Nutrient Management Specialist USDA-Natural Resources Conservation Service.

Brian Haggard Arkansas Water Resources Center UA Division of Agriculture Arkansas Water Resources Center.

Temporal and Spatial Variability in Nitrate in Subsurface Drains in a Midwestern Agricultural Watershed Paul Capel, USGS, National Water-Quality Assessment.

Economic and Biophysical Models to Support Conservation Policy: Hypoxia and Water Quality in the Upper Mississippi River Basin CARD Resources and Environmental.

Measuring Carbon Co-Benefits of Agricultural Conservation Policies: In-stream vs. Edge-of-Field Assessments of Water Quality. Measuring Carbon Co-Benefits.

U.S. Department of the Interior U.S. Geological Survey Importance of Ground-Water Flow and Travel Time on Nitrogen Loading from an Agricultural Basin in.

Science Assessment to Support an Illinois Nutrient Reduction Strategy Mark David, George Czapar, Greg McIsaac, Corey Mitchell March 11,

Co-Benefits from Conservation Policies that Promote Carbon Sequestration in Agriculture: The Corn Belt CARD, Iowa State University Presented at the Forestry.

Virginia Assessment Scenario Tool VAST Developed by: Interstate Commission on the Potomac River Basin.

The Importance of Watershed Modeling for Conservation Policy Or What is an Economist Doing at a SWAT Workshop?

Assessing Alternative Policies for the Control of Nutrients in the Upper Mississippi River Basin Catherine L. Kling, Silvia Secchi, Hongli Feng, Philip.

Watershed Management Assessment Through Modeling: SALT and CEAP Dr. Claire Baffaut Water Quality Short Course Boone County Extension Office April 12, 2007.

Iowa Nutrient Load Estimations for Point and Non-point Sources Iowa DNR November 14, 2012.

Cover crop economics: estimating a return on investment Liz Juchems and Jamie Benning.

Gulf of Mexico Hypoxia and Mississippi River Basin Nutrient Losses Herb Buxton, USGSRob Magnien, NOAA Co-Chairs, Monitoring, Modeling, and Research Workgroup,

Least Cost Control of Agricultural Nutrient Contributions to the Gulf of Mexico Hypoxic Zone Sergey Rabotyagov, Todd Campbell, Manoj Jha, Hongli Feng,

Trace that Nitrate An Overview of “Nitrate Stable Isotopes: Tools for Determining Nitrate Sources Among Different Land Uses in the Mississippi Basin” by.

Soils Genesis and Characterization Department of Agricultural and Biological Engineering University of Illinois at Urbana-Champaign.

Ground Water Age and Chemistry Data along Flow Paths: Implications for Trends and Transformations of Nutrients and Pesticides Jim Tesoriero,

Science Assessment to Support an Illinois Nutrient Reduction Strategy Mark David, Greg McIsaac, George Czapar, Gary Schnitkey, Corey Mitchell University.

Gulf of Mexico Hypoxia and Nutrient Management in the Mississippi River Basin Herb Buxton, U.S. Geological Survey.

Summary of supplementary data GLPF Grant- Team meeting #5 July 23, 2013.

1. The Study of Excess Nitrogen in the Neuse River Basin “A Landscape Level Analysis of Potential Excess Nitrogen in East-Central North Carolina, USA”

Relating Surface Water Nutrients in the Pacific Northwest to Watershed Attributes Using the USGS SPARROW Model Daniel Wise, Hydrologist US Geological Survey.

Opportunities for Collaboration on Water- Quality Issues in the Mississippi River Basin Herb Buxton, Office of Water Quality.

Science Assessment to Support an Illinois Nutrient Loss Reduction Strategy Mark David, Greg McIsaac, George Czapar, Gary Schnitkey, Corey Mitchell University.

Team Meeting #5, Great Lakes Protection Fund Grant A Phosphorus Soil Test Metric To Reduce Dissolved Phosphorus Loading to Lake Erie Heidelberg University.

Solving Water Pollution Problems in the Wakulla Springshed The City of Tallahassee’s Efforts to Reduce Stormwater Pollution Hydrogeology Workshop May 12-13,

Effect of Potential Future Climate Change on Cost-Effective Nonpoint Source Pollution Reduction Strategies in the UMRB Manoj Jha, Philip Gassman, Gene.

Minnesota BMP CHALLENGE SM Workshop WELCOME!. THE MINNESOTA RIVER WATERSHED All or portions of 38 MN counties 13 major watershed management units ~90%

National Assessment for Cropland. Analytical Approach Sampling and modeling approach based on a subset of NRI sample points. Farmer survey conducted to.

Updates on Current Science of Nutrient Flows and Conservation Actions in Iowa Dan Jaynes Panel: Bill Crumpton, Matt Helmers, Tom Isenhart, Dan Jaynes,

Request approval to proceed to EMC with 2014 Tar-Pamlico River Basin Plan.

Impacts of Livestock Waste on Surface Water Quality By the North Dakota Department of Health Division of Water Quality For the Livestock Manure Nutrient.

Nutrients and the Next Generation of Conservation Presented by: Tom Porta, P.E. Deputy Administrator Nevada Division of Environmental Protection President,

Nitrogen Budgets for the Mississippi River Basin using the linked EPIC-CMAQ-NEWS Models Michelle McCrackin, Ellen Cooter, Robin Dennis, Jana Compton, John.

A Mass Balance Approach to Evaluate Salinity Sources in the Turlock Groundwater Sub-basin Presentation to Technical Advisory Committee, Central Valley.

Illinois Nutrient Loss Reduction Strategy - NLRS

Iowa Agriculture Water Alliance

Science Assessment to Support an Illinois Nutrient Reduction Strategy

What Is Up with Soybean Yields?

Jacob Piske, Eric Peterson, Bill Perry

Overview of Climate Impact Assessment Framework and Implementation

Karl Williard and Jon Schoonover Department of Forestry

Watershed Assessment of Detroit River Loads to Lake Erie

Presentation transcript:

Science Assessment to Support an Illinois Nutrient Reduction Strategy Mark David, George Czapar, Greg McIsaac, Corey Mitchell August 8,

Technical Tasks develop a science based technical assessment of: – current conditions in Illinois of nutrient sources and export by rivers in the state from point and non- point sources – methods that could be used to reduce these losses and estimates of their effectiveness throughout Illinois – estimates of the costs of statewide and watershed level application of these methods to reduce nutrient losses to meet TMDL and Gulf of Mexico goals

Steps we will take 1.determine current conditions 2.identify critical watersheds 3.estimate potential reductions and costs 4.develop scenarios

1. Current Conditions nutrient (nitrate and total P) loads from major river basins of Illinois – estimates of point and non-point sources – compare with – determine direction of loads determine current agricultural management practices across the state – nutrient inputs and management (fertilizers and manure) – current cropping practices – N and P loads and yields from water quality data

Point Source P Analysis began with IEPA’s total P analysis – USEPA nutrient loading tool that is linked to the Integrated Compliance Information System (ICIS) – focused on larger point sources in state IEPA focused on 108 sources (used IAWA request for data) 42 facilities responded with P data we added one additional facility (Decatur) also looked at the other majors and all minors – mostly used ICIS concentrations for total P – IEPA knowledge of industrial sources for total P concentrations – some industrial sources have shut down; actual number is currently less

Point Source N Analysis solicited total N and nitrate data from operators via IAWA – received useable data from 31 facilities (1.3 to 712 MGD, median 12 MGD) – most provided 5-years of data (2008 to 2012) total N 16.8 mg N/L; nitrate-N 14.9 mg N/L applied to other facilities in ICIS N database – average from typical plants in survey – applied to 392 sources in ICIS – all POTW’s

Point Source N Loads Total NNitrate-N 1000 tons N yr -1 (392 sources) State Illinois River Green River Big Muddy Kaskaskia River Little Wabash Rock River Vermilion River Embarras River All other basins State (David and Gentry, 2000) 39.0 State consumption of N (David et al., 2010) 56.0

Point Source P Loads Total P (1000 tons P yr -1 ) (all, 1660 sources)(majors, 263) * State Illinois River Green River 0.01 Big Muddy Kaskaskia River Little Wabash Rock River Vermilion River Embarras River All other basins State (David and Gentry, 2000) 6.67 State consumption of P (Jacobson et al., 2011) 5.92 *this number is from ICIS 2009, some are no longer operational

Riverine fluxes used USGS flow data and IEPA and USGS nutrient data for 1980 through 2011 eight major rivers in state (drain 74% of state) – assumed to represent all of the state used both linear interpolation for total N, nitrate-N, dissolved reactive P (DRP), and total P; USGS WRDTS for nitrate-N, DRP, and total P Rock River contribution by difference in stations or by assuming outlet represents Illinois well

Load Estimators no standard method, unless you have a concentration every day – much argument about various methods interpolation is simple, and works well for larger rivers and nutrients such as nitrate-N for P, interpolation has limitations at high flows, when most P loss occurs (Royer et al., 2006) – Weighted Regressions on Time, Discharge, and Season is newer USGS approach (Hirsch et al., 2010)

Riverine fluxes continued interpolation and WRDTS gave similar results for nitrate-N; for DRP and total P WRDTS gave higher estimates for smaller rivers – Illinois River nearly the same for both nitrate-N and total P with either method – Rock River best estimated by difference between upstream and downstream sites we used interpolation for nitrate-N and total N, WRDTS for DRP and total P for final estimates

Riverine N and P Fluxes WaterNitrate-NTotal NDRPTotal P 10 9 m 3 yr tons N or P yr -1 David & Gentry (2000) Point sources Percent of load Point sources David & Gentry (2000) 1647

Flow and Nutrient Loads

Trends through time no significant trend for flow using linear regression of annual volume regression model with flow and time – for nitrate, R 2 =0.77, flow p < , year not significant – for total P, R 2 =0.97, flow and year both significant at p < – for DRP, R 2 =0.96, flow and year both significant at p <

Riverine N and P loads ( ) Nitrate-NTotal P 1000 tons N or P yr -1 State Illinois River Green River Big Muddy Kaskaskia River Little Wabash Rock River Vermilion River Embarras River

Riverine Loads through Time

Illinois Compared with MRB

Illinois as % of MRB David and Gentry (2000) 15% for total N, 10% for P

N and P Yields for State, 1980 to 1997 From David and Gentry (2000)

N and P Yields for State, 1997 to 2011

Point and agricultural sources ( )

Dissolved Reactive P versus Total P

Goal or Target 45% reduction in 1980 to 1996 loads – nitrate-N target of 100,000 tons N yr -1 – total P target of 8,500 tons P yr -1 larger reductions needed from 1997 to 2011 average loads – 186,000/86,000 tons N as nitrate-N needed (46%) – 17,000/8,500 tons total P needed (50%) example reduction for point source P – all majors P reduction to 1 mg P/L limit, 0.7 mg P/L average would give a 4,800 ton P reduction

Point and agricultural sources ( )

Nitrate-N and Total P Targets Red line is target, purple is average 1997 to 2011

2. Critical Watershed Identification identify 8 digits HUCs with the highest nutrient yields and loads to the Gulf of Mexico identify watersheds with nutrient impaired water bodies (303d list) determine overlap estimate point and non-point sources of N and P within watersheds

3. Estimate Potential Reductions and Costs estimate field-level effectiveness of various agricultural management practices – utilize SAB, Iowa, and Lake Bloomington Project estimates – knowledge in Illinois determine possible point source reductions estimate costs – Gary Schnitkey (agricultural economist) will lead – initial investments – likely to annualize costs over 25 years

Combined MLRA’s

Agricultural Management by MLRA Combined MLRA DescriptionCorn (acres) Soybean (acres) Wheat (acres) Drained acres (% of crop acres) Corn yield (bushels /acre) Soybean yield (bushels /acre) MLRA 1 Northern Illinois drift plain515,905224,18620, ,491 (39)16148 MLRA 2 Northeastern Illinois heavy till plain1,532,1001,111,88542,404 2,063,695 (78)15039 MLRA 3 Northern Mississippi Valley163,50752,4321,975 20,942 (10)16050 MLRA 4Deep loess and drift5,579,9803,343,44476,078 5,437,807 (61)16452 MLRA 5Claypan1,609,6331,991,939352, ,087 (9)12839 MLRA 6Thin loess and till664,242689,773161, ,971 (17)13042 MLRA 7 Central Mississippi Valley, Northern Part2,058,8531,288,68673,884 1,284,588 (38)15549 MLRA 8 Sandstone and shale hills and valleys83,969115,24410,658 49,565 (25)10333 MLRA 9 Central Mississippi Valley, Western Part203,736314,66278,250 23,769 (5)12539 Sum12,411,9259,132,251817,4609,705,916 (43) Average crop acres and yields 2008 through 2012

Agricultural Management by MLRA Combined MLRA DescriptionEstimated corn fertilizer (lbs N/acre/yr) Estimated corn fertilizer + manure (lbs N/acre/yr) Row crops (acres) Nitrate-N yield per row crop acre (lbs N/acre/yr) MLRA 1 Northern Illinois drift plain , MLRA 2 Northeastern Illinois heavy till plain ,686, MLRA 3 Northern Mississippi Valley , MLRA 4Deep loess and drift ,999, MLRA 5Claypan ,954, MLRA 6Thin loess and till ,515, MLRA 7 Central Mississippi Valley, Northern Part ,421, MLRA 8 Sandstone and shale hills and valleys , MLRA 9 Central Mississippi Valley, Western Part , Sum ,361,636

Agricultural Management by MLRA Combined MLRA DescriptionEstimated Corn fertilizer (lbs N/acre/yr) Estimated Corn fertilizer + manure (lbs N/acre/yr) Row crops (acres) Nitrate-N yield per row crop acre (lbs N/acre/yr) MLRA 1 Northern Illinois drift plain , MLRA 2 Northeastern Illinois heavy till plain ,686, MLRA 3 Northern Mississippi Valley , MLRA 4Deep loess and drift ,999, MLRA 5Claypan ,954, MLRA 6Thin loess and till ,515, MLRA 7 Central Mississippi Valley, Northern Part ,421, MLRA 8 Sandstone and shale hills and valleys , MLRA 9 Central Mississippi Valley, Western Part , Sum ,361,636

4. Develop Scenarios combine possible point source reductions and field level agricultural reductions – percent reduction by practice – costs of implementation – target 45% reductions in N and P scale-up to critical watersheds and statewide provide a range of scenarios to meet reduction targets – area needed by practice – initial investment and annualized costs