Your search keyword '"Muy, S"' showing total 2 results

1. Cation- and pH-Dependent Hydrogen Evolution and Oxidation Reaction Kinetics

Author

Botao Huang, Yanming Wang, Yang Shao-Horn, Yirui Zhang, Ying Jiang, Jeffrey C. Grossman, Yizhi Song, Yu Katayama, Sifan You, Reshma R. Rao, Adam P. Willard, Kang Xu, Tao Wang, Livia Giordano, Sokseiha Muy, Wendu Ding, Kyaw Hpone Myint, Huang, B, Rao, R, You, S, Hpone Myint, K, Song, Y, Wang, Y, Ding, W, Giordano, L, Zhang, Y, Wang, T, Muy, S, Katayama, Y, Grossman, J, Willard, A, Xu, K, Jiang, Y, and Shao-Horn, Y

Subjects

Born model, reorganization energy, Chemistry, reaction entropy, Kinetics, Infrared spectroscopy, Exchange current density, interfacial water, Electrolyte, structure-making/breaking ion, Redox, Article, Marcus-Hush-Chidsey formalism, Reaction rate, hydrogen evolution/oxidation reaction, Molecular dynamics, Marcus−Hush−Chidsey formalism, Physical chemistry, Water splitting, interfacial static dielectric constant, QD1-999

Abstract

The production of molecular hydrogen by catalyzing water splitting is central to achieving the decarbonization of sustainable fuels and chemical transformations. In this work, a series of structure-making/breaking cations in the electrolyte were investigated as spectator cations in hydrogen evolution and oxidation reactions (HER/HOR) in the pH range of 1 to 14, whose kinetics was found to be altered by up to 2 orders of magnitude by these cations. The exchange current density of HER/HOR was shown to increase with greater structure-making tendency of cations in the order of Cs+ < Rb+ < K+ < Na+ < Li+, which was accompanied by decreasing reorganization energy from the Marcus-Hush-Chidsey formalism and increasing reaction entropy. Invoking the Born model of reorganization energy and reaction entropy, the static dielectric constant of the electrolyte at the electrified interface was found to be significantly lower than that of bulk, decreasing with the structure-making tendency of cations at the negatively charged Pt surface. The physical origin of cation-dependent HER/HOR kinetics can be rationalized by an increase in concentration of cations on the negatively charged Pt surface, altering the interfacial water structure and the H-bonding network, which is supported by classical molecular dynamics simulation and surface-enhanced infrared absorption spectroscopy. This work highlights immense opportunities to control the reaction rates by tuning interfacial structures of cation and solvents.

Published

2021

2. Cation- and pH-Dependent Hydrogen Evolution and Oxidation Reaction Kinetics.

Author

Huang B, Rao RR, You S, Hpone Myint K, Song Y, Wang Y, Ding W, Giordano L, Zhang Y, Wang T, Muy S, Katayama Y, Grossman JC, Willard AP, Xu K, Jiang Y, and Shao-Horn Y

Abstract

The production of molecular hydrogen by catalyzing water splitting is central to achieving the decarbonization of sustainable fuels and chemical transformations. In this work, a series of structure-making/breaking cations in the electrolyte were investigated as spectator cations in hydrogen evolution and oxidation reactions (HER/HOR) in the pH range of 1 to 14, whose kinetics was found to be altered by up to 2 orders of magnitude by these cations. The exchange current density of HER/HOR was shown to increase with greater structure-making tendency of cations in the order of Cs + < Rb + < K + < Na + < Li + , which was accompanied by decreasing reorganization energy from the Marcus-Hush-Chidsey formalism and increasing reaction entropy. Invoking the Born model of reorganization energy and reaction entropy, the static dielectric constant of the electrolyte at the electrified interface was found to be significantly lower than that of bulk, decreasing with the structure-making tendency of cations at the negatively charged Pt surface. The physical origin of cation-dependent HER/HOR kinetics can be rationalized by an increase in concentration of cations on the negatively charged Pt surface, altering the interfacial water structure and the H-bonding network, which is supported by classical molecular dynamics simulation and surface-enhanced infrared absorption spectroscopy. This work highlights immense opportunities to control the reaction rates by tuning interfacial structures of cation and solvents., Competing Interests: The authors declare no competing financial interest., (© 2021 The Authors. Published by American Chemical Society.)

Published

2021