The goal of the project is the development of an overall strategy for reduction of turbidity/TSS, with sets of sediment reduction initiatives and actions for various sources, to address the Minnesota River Turbidity TMDL and the South Metro Mississippi River TSS TMDL.
The primary goal of this project is to analyze of dated sediment cores to reconstruct changes in the lake condition over the last 150 years. This will be done using multiple lines of evidence including biogeochemistry, sediment accumulation, and diatom and algal remains as biological indicators.
This project will provide notification of the potential for coal tar contamination, establish a storm water pond inventory schedule, and develop best management practices for treating and cleaning up contaminated sediments. The sampling design includes 15 stormwater ponds, 5 each from residential, commercial, and industrial land use areas. Municipalities in the metro area with MS4 permits of stormwater ponds will be contacted to nominate candidate sites for this study. GPS coordinates will be taken at all sampling sites.
USGS will complete the following activities in support of the SCSU project Assessing the Contribution of Microhabitat Differences on Biological Effects in Bluegill Sunfish in Sullivan Lake, MN-Continuation of MN Lakes Study 2010-2011. Geospatial analysis of maps, aerial photography, satellite imagery, GIS data, and field mapping (topography, bathymetry, vegetation, habitat); Bulk characterization of the physical and chemical features of the littoral zone, inflows, and outflows.
This project will evaluate and prioritize approximately 13,000 lineal feet of Lake Koronis shoreline for shoreline erosion and vegetative buffer condition. Those property owners with the most erosion, stormwater and vegetative buffer issues will be targeted to stabilize, infiltrate and buffer their shoreline. This project will also evaluate an additional 300 properties in the subcatchment area and target those properties that are best able to capture and treat stormwater from impervious surfaces.
The Minnesota Pollution Control Agency (MPCA) has identified streamflow alteration as a key stressor on aquatic life, but the characteristics of streamflow alteration acting as stressors have not been identified in the MPCA Watershed Restoration and Protection Strategy (WRAPS) process. Without indices that characterize streamflow alteration, the MPCA cannot quantitatively associate metrics of aquatic life condition to streamflow alteration. The lack of quantifiable indices limits the ability of the MPCA to assess environmental streamflow needs for streams and rivers throughout Minnesota.
This project will quantify and qualify the effectiveness of herbicide treatments and native plant re-establishment at Duck Lake through systematic vegetative surveys pre and post herbicide application and following mid-summer die-off of curly-leaf pondweed. The data and analysis will ultimately be used in the development of TMDLs, implementation and protection strategies for other lakes in the Middle Minnesota Major Watershed.
Ballast water - water carried in tanks on ships to help provide stability and aid steering - is likely the single greatest source for introduction of non-native and invasive aquatic species. Ballast water is collected in one body of water and discharged into another body of water, usually large distances apart. At least one new invasive species is found in the Great Lakes every year, with Lake Superior being particularly at risk. Scientists from the U.S.
Groundwater sample collection and analysis will be conducted for contaminants of emerging concern (CEC) at large subsurface treatment systems (LSTS) and rapid infiltration basins (RIB), using an enzyme linked immunosorbent assay (ELISA) methodology. Results from the ELISA analysis will be reported to the Minnesota Pollution Control Agency (MPCA) and used to conduct follow-up investigations at a select number of these sites.
The Minnesota Pollution Control Agency (MPCA) has identified streamflow alteration as a key stressor on aquatic life, but the characteristics of streamflow alteration acting as a stressor has not been identified in the MPCA Watershed Restoration and Protection Strategy (WRAPS) process. Without indices that characterize streamflow alteration, the MPCA cannot quantitatively associate metrics of aquatic life condition to streamflow alteration. The lack of quantifiable indices limits the ability of the MPCA to assess environmental streamflow needs for streams and rivers throughout Minnesota.
Concern for Deer Yard and Poplar lakes centers on their current trends of decreasing water transparencies often associated with phosphorus or sediment increases. Although both lakes still meet nutrient goals, trends in Secchi depth may presage emerging issues with the state of the lakes. This has further led to questions whether the productivity of the lakes have changed over time, what the natural or historical condition of the lakes were, what the current trajectory of each lake is, and how to best set management goals.
The Little Fork River and Big Fork River - USGS FLOWSED project was established to collect site specific data for streamflow, SSC, and bedload at the Littlefork and Big Fork Rivers in Northern Minnesota; use the data to evaluate the use of dimensionless sediment rating curves for the rivers; and document the results of the study in conjunction with the results from other rivers in the state for the application of regional sediment rating curves to rivers in Minnesota.
The goals of Phase I of the Marsh River Watershed (WRW) Watershed Restoration and Protection Strategy (WRAPS) project are to: 1) gather or develop watershed data needed for the development of the WRAPS project; 2) establish project and sub-basin work groups, develop a social outcomes strategy, and develop a civic engagement evaluation strategy to guide the WRAPS project; and 3) begin to identify, create, and organize tools that can be used to determine potential stressors and priority management areas.
The Minimal Impact Design Standards (MIDS) project represents the next generation of stormwater management in Minnesota. MIDS offers guidelines, recommendations and tools that help low impact development practices be implemented more uniformly across Minnesota's landscape and provides guidance to effectively implement the concepts and practices of low impact development. Products include performance goals for new development, redevelopment and linear projects, a graphic user interface calculator and flexible treatment options for sites design.
The Minimal Impact Design Standards (MIDS) project represents the next generation of stormwater management in Minnesota. The consultant was hired to conduct research and design specifications for permeable pavement and turf.
The overall goal of this project is to further develop performance standards, design standards, or other tools to enable the implementation of low-impact development and other stormwater management techniques.
This project will develop a reasonable statewide estimate of recharge using the Soil-Water-Balance (SWB) Code (Westenbroek and others, 2010), validate the simulation results, and conduct a parameter sensitivity analysis to identify the most sensitive model parameters. For the purposes of this application of the SWB application, comparing the simulation results will be conducted on selected watershed basins in the state against previously established recharge estimates.
This project will assess the exposure and effects of WWTP effluent on a model vertebrae organism, the fathead minnow. Through a series of controlled experiments, to be conducted on-site of the WWTP utilizing the Mobile Exposure Laboratory Trailer (MELT),SCSU will address (1) onset and timing of acute exposure effects, (2) downstream exposure effects, and (3) reproductive consequences of exposure for male and female fathead minnows. MPCA EAO staff will provide technical assistance and oversight of the project.
Staffing support to evaluate the performance of existing stormwater infiltration sites, as identified in the Minimal Impact Design Standards (MIDS) project. Monitor the range of existing infiltration devices in Minnesota and compare to design criteria, maintenance records, and quantify year-round infiltration rates. Develop and refine pretreatment options and standards for municipal stormwater treatment.
This project will develop databases to manage TMDL activities and track progress. It will also provide assistance to promulgate rulemaking. This project will also support agency operations to review civic engagement proposals from basin and sub basin organizations. Assistance provided to establish a coalition between organizations creating productive environments where citizens and stakeholders can come together to dialogue about issues of concern to them and create their own visions and strategies for TMDL-related change/issues in their communities.
This project will provide an interpretive assessment of nitrogen concentrations in Minnesota rivers and streams, including spatial and temporal trends based on historical data sets. The trends analyses will provide information useful for evaluating nitrogen reduction efforts in the past couple of decades.
The overall project goal is to develop complementary (same year) physical, biological, and chemical data sets for eight agency-prioritized lakes and three streams in NE Minnesota to incorporate into the overall state database for MPCA assessment purposes as well as research purposes.
The goal of this project is to better target restoration activities in the Cannon River watershed via a paleolimnological study of a selected set of the lakes addressed in the Total Maximum Daily Load (TMDL) for the watershed. The goals are to better constrain lake phosphorus budgets, and determine the magnitude of ecological change experienced by a range of lake types.
Minnesota Clean Water Funds will be used to complete a paleolimological study of the St. Louis River Estuary for the purpose of providing information critical to removing Beneficial Use Impairments in the St. Louis River Area of Concern. This project will reconstruct the biological (algal load and composition), geochemical (organic and inorganic), sediment, and mercury chronology to identify historical temporal and spatial variations in the St. Louis River Estuary in order to better understand the natural and anthropogenic drivers related to beneficial use impairments for the St.
The Arts Education in Minnesota Schools Research Project is surveying all public and private schools to collect baseline data on the status of arts education statewide to serve as a resource for making data-driven decisions. A national research and evaluation company, Quadrant Arts Education Research, is conducting the study, comprised of three elements.
The purpose of this project is to assess the amount of land in the Root River watershed that is treated by structural best management practices (BMPs); more specifically, Water and Sediment Control Basins. The 2016 Root River Watershed Restoration and Protection Strategy (WRAPS) report recommended reducing sediment loss from upland areas and reducing nitrate loading to streams from runoff. Understanding the location and density of these BMPs will is important for targeting future watershed protection and restoration efforts.
The purpose of the project is to collect data to represent the ambient condition of the lakes and streams of the Rum River Watershed within Mille Lacs, Isanti and Sherburne Counties that is needed to determine if thresholds set to protect designeated uses, such as aquatic recreation and aquatic life, are being met .
The goal of this project is to investigate nitrate transport and the sources of nitrate in karst for more effective implementation of best management practices that will reduce nitrate concentrations in ground and surface water.
The Statewide Sediment Network was established to measure the levels of suspended sediment concentrations and particle size distributions at eight sites across Minnesota to evaluate the amount of sediment carried by rivers. USGS sample collection and laboratory analysis techniques provide a more rigorous, robust, and technically accurate measure of sediment in water than the current use of total suspended solids as the measure of sediment in water.
The goal of this project is to update and revise the Twin Cities Metro Area (TCMA) Chloride Management Plan to a Statewide Chloride Management Plan (CMP). The Statewide CMP will provide stakeholders the information and tools necessary to improve and/or maintain water quality with respect to chloride.
The goal of this project will be to research and develop statewide winter maintenance best management practices (BMPs) for inclusion in the Statewide Chloride Management Plan and Winter Maintenance Assessment tool (WMAt). The WMAt is a necessary technical resource and planning tool for stakeholders and permittees to implement the chloride reduction strategies described in the Statewide Chloride Management Plan.
This project will conduct on-going sampling and lab analysis for suspended sediment concentration at select sites. It will also develop real-time continuous suspended sediment concentration measurements using turbidity and Acoustic Doppler Velocity Meter sensors, data analysis and draft United States Geological Survey (USGS) Scientific Investigations Report, and comparison of sampling and laboratory methods for total suspended solids and suspended sediment concentrations.
This project will result in updates to existing information and incorporation of new information into the Minnesota Stormwater Manual. The information is used by stormwater practitioners to implement the most effective and cost-efficient practices for managing stormwater runoff volume and pollutants, in addition to meeting regulatory requirement associated with stormwater permits.
This project will result in updates to existing information and incorporation of new information on active construction site erosion prevention and sediment control into the Minnesota Stormwater Manual. The information is used by stormwater practitioners to implement the most effective and cost-efficient practices for managing stormwater runoff volume and pollutants, and to meet regulatory requirements associated with stormwater permits.
This project will complete a Acetochlor Impairment Response Report. This report will combine and coordinate information relating to actions being done in direct response to the acetochlor water quality impairments with those being done and support MDA’s on-going responsibility to assure pesticides are used in a manner that does not cause unreasonable adverse effects on the environment.
This project will apply the Sunrise River watershed computer model generated under previous projects to selected scenarios of land-cover and land-management changes. The watershed model calibrated to conditions in the late 1990s will form the initial baseline against which all other model runs will be contrasted. Scenarios to be run will include changes in future land cover, agricultural practices, urban practices, and natural resource management.
This project will complete a chloride management plan which will lay out a strategy for addressing chloride impacts to our surface waters for the 7-county metropolitan area. This chloride management plan will satisfy EPA requirements for impaired waters, address waters not yet listed, and develop a strategy to protect waters that are currently meeting the water quality standards.