High entropy alloy catalysts
Established in 1963, the R&D 100 Awards is the only S&T (science and technology) awards competition that recognizes new commercial products, technologies and materials for their technological significance that are available for sale or license. The R&D 100 Awards have long been a benchmark of excellence for industry sectors as diverse as telecommunications, high-energy physics, software, manufacturing, and biotechnology. This 2021 R&D 100 winner is listed below, along with its respective category.
Category: Mechanical/Materials
Developers: University of Maryland
Co-Developers: Johns Hopkins University
United States
Product Description:Catalysts are the enabling technology for the current chemical industry and clean energy applications such as battery and fuel cell cars. However, current catalysts have significant challenges such as structural instability and high cost. Finding new and better catalysts is paramount yet largely limited by immiscibility among elements and slow experimentation. Researchers at the University of Maryland invented a disruptive high-temperature shock technique (e.g., 2000 K within 1 sec) and opened a new material space of multielement high entropy alloy catalysts, which exhibit significantly higher performance and stability than few-element catalysts. The rapid synthesis further enables data-driven, accelerated exploration, and continuous optimization in the unlimited multielement space for various catalytic reactions. This technology was initially reported in Science and further developed as a product in 2019. It has raised significant interests from industry and government agencies (e.g. funding from Maryland Innovation Initiative and Dept. of Energy ARPA-E). High entropy alloy catalysts will become next-generation, game-change catalysts for a wide range of fields, including battery and fuel cells, chemical and drug production.
Developers: University of Maryland
Co-Developers: Johns Hopkins University
United States
Product Description:Catalysts are the enabling technology for the current chemical industry and clean energy applications such as battery and fuel cell cars. However, current catalysts have significant challenges such as structural instability and high cost. Finding new and better catalysts is paramount yet largely limited by immiscibility among elements and slow experimentation. Researchers at the University of Maryland invented a disruptive high-temperature shock technique (e.g., 2000 K within 1 sec) and opened a new material space of multielement high entropy alloy catalysts, which exhibit significantly higher performance and stability than few-element catalysts. The rapid synthesis further enables data-driven, accelerated exploration, and continuous optimization in the unlimited multielement space for various catalytic reactions. This technology was initially reported in Science and further developed as a product in 2019. It has raised significant interests from industry and government agencies (e.g. funding from Maryland Innovation Initiative and Dept. of Energy ARPA-E). High entropy alloy catalysts will become next-generation, game-change catalysts for a wide range of fields, including battery and fuel cells, chemical and drug production.
Synthesis of high entropy alloy catalysts reported as the cover of Science