Charles McCrory, «Immobilization of Molecular
Electrocatalysts in a Coordinating Membrane to Enhance Their Activity and Selectivity for CO2 Reduction»
Not exact matches
In order to create less expensive electrocatalysts that work well in an alkaline environment, researchers have to know exactly how the reaction unfolds, and what its most essential mechanisms ar
In order to create less expensive
electrocatalysts that work well
in an alkaline environment, researchers have to know exactly how the reaction unfolds, and what its most essential mechanisms ar
in an alkaline environment, researchers have to know exactly how the reaction unfolds, and what its most essential mechanisms are.
A paper by Yan's research group, published
in the Jan. 8 issue of the multidisciplinary journal Nature Communications, helps pin down the basic mechanisms of the fuel - cell reaction on platinum, which will help researchers create alternative
electrocatalysts.
With a deep understanding of the mechanisms of electrode reactions
in DMFCs, the researchers designed and produced noble metal - based heterogeneous
electrocatalysts with enhanced catalytic activity and high selectivity for MOR and ORR.
Working with FENG Yan, a doctoral student, and LIU Hui, an assistant professor, YANG used selective
electrocatalysts to run a DMFC at methanol concentrations up to 15 M, an alternative method for solving the methanol crossover
in DMFCs.
The
electrocatalyst is safer and more stable than the volatile compounds found
in lithium batteries, and can function
in rain, extreme temperatures and other harsh conditions.
LIG can be written into target materials
in patterns and used as a supercapacitor, an
electrocatalyst for fuel cells, radio - frequency identification (RFID) antennas and biological sensors, among other potential applications.
Gold and silver represent the «gold standard»
in the world of
electrocatalysts for conversion of carbon dioxide to carbon monoxide.
Other flow batteries contain precious metal
electrocatalysts such as the platinum used
in fuel cells.
Scientists around the world, including those at PNNL, will continue using the principles described
in this review to design molecular
electrocatalysts with earth - abundant metals.
Methods: Scientists has been developing molecular
electrocatalysts for the oxidation of hydrogen, a common process
in fuel cells, which could use hydrogen fuel created from renewable energy.
In JCAP, Dr. Ager is investigating interactions of carbon - based supports with CO2 - reduction
electrocatalysts.
«Distant Protonated Pyridine Groups
in Water - Soluble Iron Porphyrin
Electrocatalysts Promote Selective Oxygen Reduction to Water.»
Piotr Zelenay of Materials Synthesis and Integrated Devices (MPA - 11) is world - recognized
in the area of inexpensive, nonprecious metal
electrocatalysts intended to replace platinum
in polymer fuel cells.
The new material examined
in this study is an iron - nitrogen - carbon (Fe - N - C)
electrocatalyst, synthesized with two nitrogen precursors that developed a hierarchical pore structure to expose a large fraction of the carbon surfaces to oxygen.
The mission of the Center for Molecular Electrocatalysis is to develop a comprehensive understanding of molecular
electrocatalysts that efficiently convert electrical energy into chemical bonds
in fuels, or the reverse, convert chemical energy from fuels into electrical energy.
In JCAP, Dr. Soriaga's present research is focused on electrocatalytic reactions that underpin artificial photosynthesis; specifically, directed discovery of earth - abundant
electrocatalysts, development of advanced surface - science methods for the characterization of benchmarked catalysts, and exploration of structure - composition - activity relationships to guide the expansion of catalyst - discovery strategies.
IACS team develops high - performing bio-inspired
electrocatalyst for hydrogen generation
in an aqueous medium
In the new study, published this week in the Proceedings of the National Academy of Sciences, a team led by Berkeley Lab scientist Peidong Yang discovered that an electrocatalyst made up of copper nanoparticles provided the conditions necessary to break down carbon dioxide to form ethylene, ethanol, and propano
In the new study, published this week
in the Proceedings of the National Academy of Sciences, a team led by Berkeley Lab scientist Peidong Yang discovered that an electrocatalyst made up of copper nanoparticles provided the conditions necessary to break down carbon dioxide to form ethylene, ethanol, and propano
in the Proceedings of the National Academy of Sciences, a team led by Berkeley Lab scientist Peidong Yang discovered that an
electrocatalyst made up of copper nanoparticles provided the conditions necessary to break down carbon dioxide to form ethylene, ethanol, and propanol.