The discovery can lead to the development of efficient
electrocatalysts for large scale production of synthesis gas — a mixture of carbon monoxide and hydrogen.
The PBCTF is a specialized facility designed to test novel materials such as high temperature proton exchange membranes and
electrocatalysts for the production of H2 through non-conventional electrolysis systems.
«Molecular
Electrocatalysts for Oxidation of Hydrogen Using Earth - Abundant Metals: Shoving Protons Around with Proton Relays.»
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.
Resume: Highly active and low - cost
electrocatalysts for hydrogen evolution reaction (HER) and oxygen evolution reaction (OER) are crucial due to the need for clean and renewable energy.
CoP As an Acid - Stable
Electrocatalysts for the Hydrogen - Evolution Reaction: Synchrotron - Based Operando Oxidation - State Determinations F. H. Saadi, A. I. Carim, W. Drisdell, J. Yano, N. S. Lewis, and M. P. Soriaga
Clifford Kubiak, «Molecular
Electrocatalysts for the Reduction of CO2 and the Effects of Bioinspired Secondary - Sphere Interactions on Mechanism (ENFL)»
Optimal Pattern of Bimetallic
Electrocatalysts for Efficient Conversion of Water and Carbon Dioxide to Hydrocarbons and Oxygenates M. Singh, Y. Lum, E. L. Clark, J. W. Ager, and A. T. Bell
According to lead author Professor Yuan Chen, from the University of Sydney's Faculty of Engineering and Information Technologies, the new method can be used to create bifunctional oxygen
electrocatalysts for building rechargeable zinc - air batteries from scratch.
Gold and silver represent the «gold standard» in the world of
electrocatalysts for conversion of carbon dioxide to carbon monoxide.
This work is a significant advance towards developing more efficient
electrocatalysts for water - splitting reactions and fuel generation.
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.
IACS team develops high - performing bio-inspired
electrocatalyst for hydrogen generation in an aqueous medium
Not exact matches
The open structure of the nanoframes addresses some of the major design criteria
for advanced nanoscale
electrocatalysts, namely, high surface - to - volume ratio, three - dimensional surface accessibility to reactants, and optimal precious metal use.
But these fuel cells require an
electrocatalyst — a platinum surface — to increase the reaction rate, and the cost of the precious metal makes it hard
for hydrogen fuel cells to compete economically with the internal combustion engine.
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.
For the former, they deposited layers of cobalt and phosphorus or nickel and iron onto P - LIG to make a pair of
electrocatalysts with high surface areas that proved to be durable and effective.
Charles McCrory, «Immobilization of Molecular
Electrocatalysts in a Coordinating Membrane to Enhance Their Activity and Selectivity
for CO2 Reduction»
Effects of Temperature and Gas - Liquid Mass Transfer on the Operation of Small Electrochemical Cells
for the Quantitative Evaluation of CO2 Reduction
Electrocatalysts P. Lobaccaro, M. Singh, E. L. Clark, Y. Kwon, A. T. Bell, and J. A. Ager
The work, the team suggests, provides a facile strategy
for fabricating highly efficient
electrocatalysts from earth - abundant materials
for... Read more →
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.
The JCAP Benchmarking scientists developed and implemented uniform methods and protocols
for characterizing the activities of
electrocatalysts under standard operating conditions
for water - splitting devices.
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.