They were able to achieve 100 percent oxidation of ammonia and 99 percent selectivity toward desired products with the high entropy alloy nanoparticles, proving their ability as
highly efficient catalysts.
Not exact matches
Richard Schrock, a chemist now at the Massachusetts Institute of Technology in Cambridge, and colleagues changed that picture in the early 1970s when they came up with a series of molybdenum -, tungsten -, and tantalum - based
catalysts that were
highly active and
efficient.
The compound belongs to a class of
highly conductive materials previously recognized as
efficient water - splitting
catalysts in liquid.
The Tufts researchers discovered that dispersing individual, isolated platinum atoms in much less costly copper surfaces can create a
highly effective and cost -
efficient catalyst for the selective hydrogenation of 1,3 butadiene, a chemical produced by steam cracking of naphtha or by catalytic cracking of gas oil.
Among the areas of research that inspire Dr. Cui are: the development of new technologies to further the development of electric transportation; creating new battery chemistry for grid - scale storage at ultra-low cost; and harnessing low - cost technologies for the development of
catalysts for
efficient carbon dioxide reduction and conversion into
highly valuable products and inert carbon - hydrogen bond activation.
One of those users is Dane Morgan, a professor of engineering at the University of Wisconsin - Madison who develops new materials for a wide range of applications, including
highly active
catalysts for fuel cells, stable low - work function electron emitter cathodes for high - powered microwave devices, and
efficient, inexpensive, and environmentally safe solar materials.
Researchers at Loker Hydrocarbon Research Institute and Department of Chemistry, University of Southern California, have developed a
highly efficient homogeneous Ru - based
catalyst system for the production of methanol (CH3OH) from CO2 and H2 in an ethereal solvent (initial turnover frequency = 70 h − 1 at 145 °C).
Few
catalysts are energy
efficient,
highly active, stable, and able to operate in water; however, a redesigned nickel - based
catalyst quickly and efficiently turns protons and electrons into hydrogen.