Great Lakes Bioenergy research consistently results in new discoveries and new technologies. Here, we highlight high-impact research from all three of our research areas.
In a new study, a team from the Great Lakes Bioenergy Research Center describes a multi-solvent extraction process that can isolate five major products obtained from poplar lignin.
Chemists at the Great Lakes Bioenergy Research Center (GLBRC) have developed a new approach that converts biomass into both carbohydrates and lignin-derived aromatic monomers in a single step. This approach avoids lignin degradation and mass losses that occur in traditional biomass separation methods and enables better product yields.
GLBRC scientists incorporated carbon capture and storage technologies into models of how crop and pretreatment choices influence the economic viability of a biofuel refinery. They developed a model and performed thousands of individual calculations to determine the impact of carbon capture and storage technologies, feedstock choices, and pretreatment strategies on three outcomes: energy production, environmental impacts, economic benefits.
A research team at the Great Lakes Bioenergy Research Center has developed a way to measure GWI associated with albedo, which calculates how well a crop’s surface reflectivity cools the local climate. A new study shows that albedo-induced climate mitigation from conversion of CRP lands to perennial bioenergy crops like switchgrass and restored prairie can be substantial.
Researchers at GLBRC and the South China University of Technology have developed a faster and less chemically intensive spectroscopy-based procedure called the Cysteine-Assisted Sulfuric Acid (CASA) method. The approach uses a new reagent combination of the amino acid cysteine and sulfuric acid to completely dissolve lignocellulosic biomass under less extreme conditions than traditional methods.
A key discovery by Great Lakes Bioenergy Research Center scientists reveals how root interactions among Midwest prairie perennials, including the bioenergy crop switchgrass, increase soil carbon when grown in specific pairings. These beneficial plant combinations also created more soil pores that support fungi that are associated with soil carbon accrual.
A team from the University of York and the Great Lakes Bioenergy Research Center isolated a soft-rot fungus that shows exceptional ability to break down lignocellulose. From this fungus, they identified oxidase enzyme activity that effectively cleaves one of the major bonds in lignin, a process that currently requires expensive and time-consuming pretreatment steps. The enzyme also releases potentially useful co-products and makes the remaining lignin more easily digested by other enzymes.
As the climate warms, many scientists and farmers have worried about how rising temperatures will affect agricultural systems and crop yields. Warmer air may increase evaporation and water loss from plants, leading to concerns that climate change will cause crops to require more water—either from precipitation or irrigation—in a warmer future. However, a modeling study using temperature trends projected through 2050 suggests that future yields of corn and other bioenergy crops in the Midwest may stay stable without need for expanded irrigation.
In the face of climate change, breeding strategies that can improve crop resilience and productivity across a range of environments is increasingly important, but these approaches require sufficient knowledge of the genes that underlie productivity and adaptation. By studying 732 genotypes grown at 10 experimental gardens in eight states spread across 1,100 miles, a large team of researchers have produced a high-quality reference sequence of the complex switchgrass genome.
GLBRC scientists have established a machine learning model to help explain variation in nitrous oxide emissions from agricultural soils. Trained on data collected from GLBRC field sites in Michigan and Wisconsin, the tool can predict nitrous oxide fluxes much more accurately than existing models.