Funding will support the project team's small-scale research and development of a low-loss grain-oriented steel technology to improve the efficiency of transformers used in the electric grid.
The U.S. Department of Energy (DOE) is proposing to provide federal funding to the University of Minnesota (UMN) to design, evaluate, fabricate, an…
Funding will support the project team's small-scale research and development of a caustic aqueous phase reforming (C-APR) technology for the purpose of producing carbon-negative, clean hydrogen from raw bioethanol (i.e., ethanol plus water solution from the fermentation process).
A general-use laboratory for fuel, energy, catalytic, surface, and materials science. The laboratory will contain synthesis and characterization of…
The U.S. Department of Energy (DOE) is proposing to provide federal funding to Oregon State University (OSU) for the characterization, modification…
Funding will support the project team's small-scale research and development of an ultra-high power density alternating current (AC) - direct current (DC) Universal Power Mover (UPM), an electrically and mechanically stackable, low-to-medium voltage compatible, reconfigurable building block technology for the purpose of enabling electrical energy flow to and from the point of use, applicable among industries that use distributed grid-tiered systems, such as EV charging and energy storage.
Funding will support the project team's small-scale research and development of a high-throughput, performance-specific, and cost-effective generative materials design and discovery framework tailored for hydrogen (H2) fueled gas turbine technologies, applicable to power generation and transportation industries.
Funding will support the project team's small-scale research and development of Structured Plasma Cell-Thermionic Energy Conversion (SPACE-TEC), a nuclear fuel technology that directly converts nuclear heat into electricity, eliminating the need for a conventional power generation system.
Funding will support the project team's small-scale research and development of a robotic-assisted laser joining technology for the purpose of enabling robust, high-temperature-resistant, and hermetic joining of complex and large silicon carbide (SiC)-based materials.
Operate an advanced sensors development laboratory at the NETL Pittsburgh Site in B-83, R-315., B-83, R-221., B-94, R-003., B-94, R-206., B-94, R-2…