The Greater Blue Earth River Basin Alliance (GBERBA) is a joint powers organization consisting of ten member Counties and SWCDs encompassing the Blue Earth, Le Sueur and Watonwan Watersheds. Our mission is to lead in the implementation and promotion of economically viable watershed activities through the combined efforts of local partners. We have identified two target areas in the GBERB (Greater Blue Earth River Basin) where high levels of nitrates directly affect public water supply.
This project will create and optimize eDNA assays to detect the presence of 8 endangered or threatened mussel species around Buffalo Slough near Prairie Island Indian Community.
Geologic atlases provide maps/databases essential for improved management of ground and surface water. This proposal will complete current projects and start new projects to equal about 4 complete atlases.
Get the Lead Out is focused on protecting common loons and wildlife through education and outreach about the danger of lead fishing tackle and promoting lead-free tackle alternatives.
The Thief River is the source of drinking water for the City of Thief River Falls. The river's other designated uses also include recreation and aquatic life. Water quality monitoring conducted by local agencies discovered that the Thief River is not meeting state water quality standards for both turbidity (muddiness) and dissolved oxygen. Each year, approximately 12,376 tons of sediment is deposited into the Thief River Falls reservoir by the Thief River. That is the equivalent of over 1,200 dump trucks full of dirt.
The purpose of this project is to prepare a Watershed Restoration and Protection Strategy (WRAPS) Report and Total Maximum Daily Load (TMDL) Study for public notice. This project will include addressing and incorporating Minnesota Pollution Control (MPCA) review comments in both documents. The TMDL Study has been submitted to the United States Environmental Protection Agency (USEPA) for preliminary review. USEPA comments will be addressed prior to public notice.
The goal of this project is to construct watershed models for the Grand Marais Creek and Snake River Watersheds and perform an initial hydrologic calibration using Hydrologic Simulation Program FORTRAN (HSPF).
In the early 1900s, a joint State and County drainage project constructed a 1 mile outlet channel to Grand Marais Creek to provide a shorter outlet to the Red River and effectively abandoned the lower 6 miles of the natural channel. In recent times, the ditch has eroded from its original shape to a channel of steep gradients and unstable banks. This has resulted in head cutting of the channel and nearly continuous channel erosion and bank sloughing with the effect of depositing up to an estimated annual average of 700 tons of sediment into the Red River.
Directly restore six miles of stream habitat, the hydrologic conditions needed to support 400 acres of habitat corridor, and effectively reconnect more than 20 miles of the Grand Marais Creek.
Per Minnesota Laws, 2011, 1st Special Session, Chapter 6, Article 4, Section 2, Subd. 6, "These amounts are appropriated to the commissioner of administration for grants to the named organizations for the purposes specified in this subdivision.
Per Minnesota Laws, 2009, Chapter 172, Article 4, Section 2, Subd. 5, "Funds in this subdivision are appropriated to the commissioner of the Department of Administration for grants to the named organizations for the purposes specified in this subdivision. Up to one percent of funds may be used by the Department of Administration for grants administration. Grants made to public television or radio organizations are subject to Minnesota Statutes, sections 129D.18 and 129D.19."
The project will estimate sand-sized sediment loads for the Blue Earth and Le Sueur Rivers using United States Geological Survey (USGS) measurements to create an overall sediment budget for the rivers in conjunction with already completed fine sediment budgets. The development of the estimates from USGS data and comparisons will strengthen the understanding of the magnitude of the sand component of the total sediment load in the rivers.
