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.
MSU-Mankato Water Resources Center in the Mankato area will provide conventional pollutant monitoring at the following sites: Beauford Ditch, Big Cobb River, Blue Earth River, Le Sueur River (3), Little Cobb River, Minnesota River (2), Watonwan River.
This project will support the monitoring of two sites on the Cannon River throughout the field seasons of 2013 and 2014 during storm events and baseflow conditions to capture 25 samples per year at each site according to the WPLMN objectives. The information gathered from these samples and site visits will be compiled for reporting purposes and for use in calculating pollutant loading using the FLUX32 model.
This project will monitor six sites within the Minnesota River Basin: Hawk Creek near Maynard, Hawk Creek near Granite Falls, Beaver Creek near Beaver Falls, Yellow Medicine River near Granite Falls, Yellow Medicine River near Hanley Falls, and Spring Creek near Hanley Falls. The sites will be monitored according to MPCA’s Major Watershed Load Monitoring (WPLMN) Standard Operating Procedure, which is the procedure being followed for sites currently monitored by the Hawk Creek Watershed Project (HCWP).
This project will work with the MPCA to conduct watershed pollutant load monitoring at four sites in the Chippewa River watershed and one site in the neighboring Pomme de Terre River watershed . The Chippewa River Watershed Project (CRWP) team will also aid the MPCA in measuring and comparing regional differences and long-term trends in water quality. The goal is to collect quality data and complete load calculations for the five sites using the MPCA's established protocols.
The Pope County Water Plan has identified surface water quality and erosion control as top priority resource concerns. These two priorities account for 33% of the phosphorus loading to Lake Emily. The Lake Emily Watershed Best Management Practices (BMP) Prioritization Project will provide GIS-based water quality analysis to assist the Pope Soil and Water Conservation District in determining effective locations for BMP implementation and will prioritize the areas from high to low for phosphorus, nitrogen, and sediment delivery from contributing runoff during rainfall events.
The City of Myrtle is an unsewered community in Freeborn County. Thirty-one of thirty-two properties are connected to a community straight pipe, which discharges raw sewage into Deer Creek, a tributary of the Cedar River and are classified as an imminent threat to public health (ITPHS). This project will provide cost-share assistance to 28 low income property owners, who are connected to the City of Myrtle community straight pipe, for construction of individual subsurface sewage treatment systems.
Pope Soil and Water Conservation District, partnered with Natural Resources Conservation Service staff and landowners, will install 22 targeted water and sediment control structures in two priority subwatersheds (Trappers Run and Minnewaska). These structures have the potential to reduce sediment load by 514 tons per year, and phosphorus by 440 pounds per year.
The City of Glenwood Water Quality Assessment & Best Management Practice Prioritization Project will include an assessment and analysis of approximately 1,796 acres affecting water quality and contributing runoff to Lake Minnewaska. By implementing this water quality analysis and assessment of the City of Glenwood and sub watersheds, a reducing pollutants by 1,287 pounds per year of phosphorus and 203 tons per year of sediment.
County Ditch #8 (CD8) has been identified as an area of high erosion by the Freeborn County Drainage Authority and the Turtle Creek Watershed district. Project entails using conservation BMPs such as water and sediment control basins, grassed waterways, and alternative tile intakes to address gully and sheet and rill erosion concerns at the headwaters of CD8.
The Lake Emily Watershed BMP Targeted Implementation Project will provide funding for 48 water and sediment control projects and potential shoreline and riparian restoration. This work would address surface water quality sources identified in the water plan (Section 2-pg 11) including direct drainage from the Lake Emily sub-watersheds (070200050304, 070200050303, 070200050203, 070200050201, 070200050202) the Little Chippewa, and from upstream discharge between Lake Emily and Lake Minnewaska.
Pope SWCD has 9 motivated landowners with 21 WASCOBs, 1 lined waterway, and 1 shoreline restoration in two priority sub watersheds (Trappers Run and Minnewaska). Based on averages calculated from recently constructed WASCOBs in the West Central Area II these projects have the potential to reduce TSS by 518 T/year, and 446 lbs./year of TP. This project will provide a secondary benefit to improve downstream water quality to Lake Emily. The project will result in meeting 99% of the Lake Emily TP lbs/yr.
These funds are being used to systematically collect data and produce statistically valid estimates of the rate of soil erosion and tracking the adoption of high residue cropping systems in in the 67 counties with greater than 30% land in agricultural row crop production. Designed to establish a long term program in Minnesota to collect data and produce county, watershed, and state wide estimates of soil erosion caused by water and wind along with tracking adoption of conservation measures to address erosion.
The Benton County Water Plan advisory committee has the goal of protecting groundwater resources in Benton County. One of the methods identified is to seal unused wells. In 2013, Benton Soil and Water Conservation District completed an aggressive campaign to identify unused wells. We used several sources to locate potential wells, completed site visits for many wells and collected site information to assisting in prioritizing limited cost share resources.
These funds are being used to systematically collect data and produce statistically valid estimates of the rate of soil erosion and tracking the adoption of high residue cropping systems in counties with greater than 30% land in agricultural row crop production. Designed to establish a long term program in Minnesota to collect data and produce county, watershed, and state wide estimates of soil erosion caused by water and wind along with tracking adoption of conservation measures to address erosion.
This project targets nutrient reductions within the Mayhew and Big Elk Lake watersheds. The Benton Soil and Water Conservation District will work with farmers in implementing a variety of conservation practices including, but not limited to cropland erosion control projects, riparian pasture management, and nutrient management and feedlot pollution control systems. These strategies were identified through Total Daily Maximum Load Studies.
Little Rock Lake experiences severe algae blooms due to excess phosphorus and these blooms are the worst known regionally. The goal of this project is to reduce algae blooms, improve water clarity, and avoid risk of drinking water contamination. The project will result in installing one farmer nutrient management project , four cover crops, two lakeshore buffer strips, six septic systems that also demonstrated an imminent threat to public health, six erosion control projects , one wetland restored, and one feedlot runoff control system.
A completed Total Maximum Daily Load (TMDL) study has identified mid to late summer phosphorus loading as a significant stressor to lakes and streams within the Big Elk Lake watershed. While this comprehensive study serves its role as the unifying document that identifies pollutants and sources, further work is required in order to develop site-specific Best Management Practices, design these practices, and oversee their implementation in order to reach clean water goals.
Lake Emily is a high priority recreational lake in Pope County and is currently not meeting state water quality standards due to high phosphorus levels. This project will provide funding for 26 water and sediment control projects with potential shoreline and riparian restoration projects. This work will address surface water quality sources including both direct drainage and upstream discharge. Collectively, these projects have the potential to annually reduce sediment and phosphorus leaving the field which will directly address 15% of Lake Emily's phosphorus reduction goal.
This project will address nutrient impairments of the Sauk River and Sauk River Chain of Lakes (SRCL) by minimizing runoff from 5 high priority feedlots. Specifically, contaminated runoff from 5 feedlots upstream of the SRCL will be eliminated. The sites were prioritized based on the Minnesota Feedlot Annualized Runoff Model index ratings and the location of these feedlots are within a Drinking Water Supply Management Areas.
This project will decrease peak flows and associated water quality issues such as sediment and phosphorus on County Ditch 68, Mud Lake, and Fountain Lake. Practices include a 40-acre storage and treatment wetland, two cropped and altered wetland restorations of an acre each, converting 32 acres of cropland to perennial cover, and two grade stabilization structures.
These funds will be utilized in cost-share for landowners to install Agricultural Best Management Practices following Little Rock Lake TMDL Implementation Plan. Example of projects include Feedlot Improvements, Waste Storage Facilities, Erosion Control BMPs, Filter Strips and Streambank Stabilizations. An estimated 830 pounds per year of phosphorus and 800 tons of sediment will be reduced annually.
The goal of this project is to achieve a 10% reduction in overall sediment discharge to the Mississippi River from the Northeast St. Cloud Drainage Area by installing one regional underground stormwater detention and treatment facility in partnership with a Neighborhood Redevelopment Project. The project will have over 16,000 cubic feet of water storage capacity treating 35 acres of stormwater runoff and is modeled to reduce sediment by 4.5 tons, which is 10% of the sediment reduction goal for this drainage area.
This proposal accelerates the strategic permanent protection of 915 acres (220 wetlands and 695 grasslands) of Waterfowl Production Areas (WPAs) open to public hunting in Minnesota. Pheasants Forever (PF) will strategically acquire parcels that are adjacent to existing public land or create corridors between complexes. All acquisitions will occur in the prairie, prairie/forest transition, or metro regions.
This proposal accelerates the protection of 1,030 acres of strategic prairie grassland, wetland, and other wildlife habitats as State Wildlife Management Areas (WMA) open to public hunting. Pheasants Forever (PF) will be acquiring tracts that build onto or create a corridor between existing protected lands which will be transferred to the MN Department of Natural Resources (MN DNR) to be included as a WMA. All acquisitions will occur within the prairie, prairie/forest transition, and metro planning regions. These areas have seen the greatest decline in upland and wetland habitat.
This programmatic proposal accelerates the protection and restoration of 1,073 acres of strategic prairie grassland, wetland, and other wildlife habitats as State Wildlife Management Areas (WMA) open to public hunting. Pheasants Forever (PF) will be protecting parcels that build onto or create a corridor between existing protected lands which will be transferred to the MN Department of Natural Resources (MN DNR) to be included as a WMA. All acquisitions will occur within the prairie, prairie/forest transition, and metro planning regions.
This proposal accelerates the strategic permanent protection of 1,003 acres (241 wetlands and 762 grasslands) of Waterfowl Production Areas (WPAs) open to public hunting in Minnesota. Pheasants Forever (PF) will strategically acquire parcels that are adjacent to existing public land or create corridors between complexes. All acquisitions will occur in the prairie, prairie/forest transition, or metro regions.