DOE & USDA Announce Bioenergy Projects

Ten projects will receive funding aimed at accelerating genetic breeding programs to improve plant feedstocks for biofuel production as well as biopower and bio-based power. The U.S Department of Energy (DOE) and the U.S. Department of Agriculture (USDA) has awarded $12.6 million in research grants designed for harnessing nonfood plant biomass to replace US DOE Energy logofossil fuels and chemicals. The agencies note that feedstock crops tend to require less intensive production practices and can grow on poorer quality land than food crops, making this a critical element in a strategy of sustainable biofuels production that avoids competition with crops grown for food.

“Biofuels and bio-based products offer the potential of homegrown American resources that can reduce our dependence on imported oil and also cut carbon emissions,” said Secretary of Energy Ernest Moniz. “This advanced research is helping us to lay the groundwork for biomass as an important part of the low-carbon future.”

The winning projects are located in California, Colorado, Illinois, Michigan, Minnesota, Missouri, New York, Texas, and Virginia. DOE’s Office of Science will provide $10.6 million in funding for eight projects, while USDA’s National Institute of Food and Agriculture (NIFA) will award $2 million to fund two projects. Initial funding will support research projects for up to three years.

Agriculture Secretary Tom Vilsack added, “Innovative research is a critical link to stimulating rural economies and creating jobs across America. These awards are part of the Obama Administration’s “all of the above” energy policy. These projects will not only support our efforts to provide a sustainable and domestic energy source for the nation, but also improve the lives of rural residents.”

New projects to be funded this year will build upon gains in genetic and genomic resources for bioenergy and biofuels. The projects will accelerate the breeding of optimized dedicated bioenergy feedstocks through a better understanding of complex interactions between bioenergy feedstock plants and their environment, allowing the development of new regionally-adapted bioenergy feedstock cultivars with maximal biomass or seed oil yield and traits leading to more sustainable production systems, such as minimal water usage and nutrient input requirements.

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