The Minnesota Department of Agriculture (MDA) has partnered with the East Otter Tail Soil and Water Conservation District (EOT SWCD) to carry out a series of workshops and expand programs that promote proper water and nitrogen management.
The main outcome of Phase III of the project will be the final deliverable of a WRAPS report that will prescribe the restoration and protection strategies for the surface water resources within the Leech Lake River Watershed. The WRAPS will provide the analytical and strategic foundation which will be essential in protecting the surface water resources within this high quality watershed. Along with the development of the WRAPS report, this project will support the development and completion of the MPCA Stressor ID and Watershed Assessment reports to be completed for this watershed.
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.
Several important milestones will be completed during this Phase (Phase II) of the Mississippi River (Headwaters) Watershed Restoration and Protection Strategy (WRAPS) project. These milestones will include the completion of the Stressor ID & Watershed Monitoring and Assessment Reports, the completion of the Zonation Modeling watershed priority planning process (through the continuation of the Civic Engagement project component), and the development of the overall WRAPS report.
This project was part of a three-state partnership to test, demonstrate and promote a simple, inexpensive and reliable new system for edge-of-field water monitoring. The University of Wisconsin-Platteville Pioneer Farm, in collaboration with UW-Platteville Engineering, has developed a low cost monitoring system that can obtain good quality, edge-of-field monitoring data in agricultural settings. By eliminating unnecessary features and assembling components in-house, the prototype monitoring system derives the majority of cost savings with minimal sacrifice in accuracy.
Within an 11-county area in southeastern Minnesota, two Nutrient Management Specialists will work directly with producers to reduce nitrogen, phosphorus, and fecal coliform runoff into surface and ground water in the region and the Mississippi River. The specialists will help producers create or revise nutrient management plans, implement Best Management Practices for manure and fertilizer use, and set up on-farm demonstration projects to support farmer-to-farmer learning.
The goal of this project is to engage citizens in local watershed monitoring, work with regional partners to promote understanding and protection of watersheds, and organize and facilitate gathering of scientific data for the benefit of water quality in the Red River Basin.
The goal of this project is to continue best management implementation according to the Redwood River Phase II Implementation Plan (1999) and install phosphorus and total suspended solids (TSS) reducing conservation practices that will help achieve the Lower Minnesota River dissolved oxygen Total Maximum Daily Load (TMDL), and the Minnesota River Turbidity TMDL. The proposed implementation of conservation practices include: water and sediment control basins, grassed waterways, grade stabilizations and streambank stabilizations.
Approximately 70 percent of all Minnesotans rely on groundwater as their primary source of drinking water. Wells used for drinking water must be properly sealed when removed from service to protect both public health and Minnesota’s invaluable groundwater resources. The Minnesota Department of Health protects both public health and groundwater by assuring the proper sealing of unused wells.
Clean Water funds are being provided to well owners as a 50% cost-share assistance for sealing unused public water-supply wells.
A joint effort of Becker and Clay Soil and Water Conservation District, the Buffalo Red Shallow Lakes and Mainstem Improvement Strategy will reduce nutrient and sediment delivery to 12 impaired lakes and impaired reaches of the Buffalo River through a targeted and prioritized approach to the implementation of Best Management Practices (BMPs). Numerous models have been combined with local knowledge to identify chief sources of constituents in the watershed and to isolate and prioritize implementation sites demonstrating the most significant gains in water quality.
The Metropolitan Council, in conjunction with CDM Smith and HKGi consultants, reorganized and expanded the water conservation tools on the water supply planning pages of the Metropolitan Council’s website. The revised toolbox was organized into an online, web-based guide format. These tools are supplemented with fact sheets and case studies that serve to educate and provide useful information to support water conservation programs and activities.
This monitoring work expands on previously established routine water quality and flow sampling to include extensive fish and aquatic invertebrate surveys. Subsequent steps include assessment of the monitoring data to determine impairments, identification of stressors that are causing impairments, development of Total Maximum Daily Load (TMDL) studies using identification of pollutant sources using computer modeling and other techniques, civic engagement, and public education as approaches in progress towards water quality goals.
Locating the sources of sediment, phosphorus, and bacteria is integral to reducing the effect they have on a water body. The completion of the West Fork Des Moines River (WFDMR) Targeting and Prioritizing Endeavor will result in a set of data that is the most cost-effective for the implementation of Best Management Practices (BMPs) for all identified priority resources. The results will be expressed as the maximum reduction of a water quality contaminant (e.g. sediment, phosphorus, bacteria) at a priority resource (e.g. an impaired stream) for a given level of investment.