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Reverse water-gas shift reaction: steady state isotope switching study of the reverse water-gas shift reaction using in situ DRIFTS and a Pt/ceria catalyst
Applied Catalysis A General
◽
10.1016/j.apcata.2005.01.013
◽
2005
◽
Vol 284
(1-2)
◽
pp. 31-38
◽
Cited By ~ 47
Author(s):
Gary Jacobs
◽
Burtron H. Davis
Keyword(s):
Steady State
◽
Water Gas Shift
◽
Water Gas Shift Reaction
◽
In Situ Drifts
◽
Reverse Water Gas Shift
◽
Shift Reaction
◽
Water Gas
Download Full-text
Related Documents
Cited By
References
Water-gas shift: steady state isotope switching study of the water-gas shift reaction over Pt/ceria using in-situ DRIFTS
Catalysis Letters
◽
10.1007/s10562-004-3447-4
◽
2005
◽
Vol 100
(3-4)
◽
pp. 147-152
◽
Cited By ~ 37
Author(s):
Gary Jacobs
◽
Adam C. Crawford
◽
Burtron H. Davis
Keyword(s):
Steady State
◽
Water Gas Shift
◽
Water Gas Shift Reaction
◽
In Situ Drifts
◽
Shift Reaction
◽
Water Gas
Download Full-text
Cyclic Steady-State Behavior of a Fixed-Bed Adsorptive Reactor for Reverse Water-Gas Shift Reaction
Chemical Engineering & Technology
◽
10.1002/ceat.201600611
◽
2017
◽
Vol 40
(5)
◽
pp. 915-926
◽
Cited By ~ 6
Author(s):
Alejandro A. Munera Parra
◽
Carsten Asmanoglo
◽
David W. Agar
Keyword(s):
Steady State
◽
Fixed Bed
◽
Water Gas Shift
◽
Water Gas Shift Reaction
◽
State Behavior
◽
Reverse Water Gas Shift
◽
Shift Reaction
◽
Water Gas
◽
Steady State Behavior
Download Full-text
CO2 methanation and reverse water gas shift reaction. Kinetic study based on in situ spatially-resolved measurements
Chemical Engineering Journal
◽
10.1016/j.cej.2020.124629
◽
2020
◽
Vol 390
◽
pp. 124629
◽
Cited By ~ 4
Author(s):
Jose A. Hernandez Lalinde
◽
Pakpong Roongruangsree
◽
Jan Ilsemann
◽
Marcus Bäumer
◽
Jan Kopyscinski
Keyword(s):
Kinetic Study
◽
Reaction Kinetic
◽
Water Gas Shift
◽
Water Gas Shift Reaction
◽
Co2 Methanation
◽
Spatially Resolved
◽
Reverse Water Gas Shift
◽
Shift Reaction
◽
Water Gas
Download Full-text
Electrochemical in-situ activation of Fe-oxide nanowires for the reverse water gas shift reaction
Applied Catalysis B Environmental
◽
10.1016/j.apcatb.2020.118826
◽
2020
◽
Vol 269
◽
pp. 118826
◽
Cited By ~ 4
Author(s):
Christopher Panaritis
◽
Johnny Zgheib
◽
Sayed A.H. Ebrahim
◽
Martin Couillard
◽
Elena A. Baranova
Keyword(s):
Water Gas Shift
◽
Water Gas Shift Reaction
◽
Fe Oxide
◽
Oxide Nanowires
◽
Reverse Water Gas Shift
◽
In Situ Activation
◽
Shift Reaction
◽
Water Gas
Download Full-text
Highly efficient Cu/CeO2-hollow nanospheres catalyst for the reverse water-gas shift reaction: Investigation on the role of oxygen vacancies through in situ UV-Raman and DRIFTS
Applied Surface Science
◽
10.1016/j.apsusc.2020.146035
◽
2020
◽
Vol 516
◽
pp. 146035
◽
Cited By ~ 5
Author(s):
Yudong Zhang
◽
Long Liang
◽
Ziyang Chen
◽
Jinjun Wen
◽
Wen Zhong
◽
...
Keyword(s):
Oxygen Vacancies
◽
Water Gas Shift
◽
Water Gas Shift Reaction
◽
Hollow Nanospheres
◽
Reverse Water Gas Shift
◽
Uv Raman
◽
Shift Reaction
◽
Water Gas
Download Full-text
Analysis and modeling of PEM fuel cell stack performance: Effect of in situ reverse water gas shift reaction and oxygen bleeding
Journal of Power Sources
◽
10.1016/j.jpowsour.2005.11.104
◽
2006
◽
Vol 159
(2)
◽
pp. 943-950
◽
Cited By ~ 18
Author(s):
G. Karimi
◽
Xianguo Li
Keyword(s):
Fuel Cell
◽
Pem Fuel Cell
◽
Water Gas Shift
◽
Water Gas Shift Reaction
◽
Performance Effect
◽
Fuel Cell Stack
◽
Reverse Water Gas Shift
◽
Shift Reaction
◽
Water Gas
Download Full-text
In situ DRIFTS studies of high-temperature water-gas shift reaction on chromium-free iron oxide catalysts
Comptes Rendus Chimie
◽
10.1016/j.crci.2010.11.007
◽
2011
◽
Vol 14
(6)
◽
pp. 534-538
◽
Cited By ~ 21
Author(s):
Amel Boudjemaa
◽
Cécile Daniel
◽
Claude Mirodatos
◽
Mohamed Trari
◽
Aline Auroux
◽
...
Keyword(s):
High Temperature
◽
Iron Oxide
◽
Water Gas Shift
◽
Water Gas Shift Reaction
◽
In Situ Drifts
◽
High Temperature Water
◽
Shift Reaction
◽
Water Gas
◽
Temperature Water
Download Full-text
In Situ Dispersion of Palladium on TiO 2 During Reverse Water–Gas Shift Reaction: Formation of Atomically Dispersed Palladium
Angewandte Chemie
◽
10.1002/ange.202007576
◽
2020
◽
Vol 132
(40)
◽
pp. 17810-17816
Author(s):
Nicholas C. Nelson
◽
Linxiao Chen
◽
Debora Meira
◽
Libor Kovarik
◽
János Szanyi
Keyword(s):
Water Gas Shift
◽
Water Gas Shift Reaction
◽
Reverse Water Gas Shift
◽
Reaction Formation
◽
Shift Reaction
◽
Water Gas
Download Full-text
Mechanistic aspects of the water–gas shift reaction on alumina-supported noble metal catalysts: In situ DRIFTS and SSITKA-mass spectrometry studies
Catalysis Today
◽
10.1016/j.cattod.2007.05.002
◽
2007
◽
Vol 127
(1-4)
◽
pp. 304-318
◽
Cited By ~ 77
Author(s):
George G. Olympiou
◽
Christos M. Kalamaras
◽
Constantinos D. Zeinalipour-Yazdi
◽
Angelos M. Efstathiou
Keyword(s):
Mass Spectrometry
◽
Noble Metal
◽
Metal Catalysts
◽
Water Gas Shift
◽
Water Gas Shift Reaction
◽
In Situ Drifts
◽
Noble Metal Catalysts
◽
Shift Reaction
◽
Water Gas
Download Full-text
Strain-assisted in-situ formed oxygen defective WO3 film for photothermal-synergistic reverse water gas shift reaction and single-particle study
Chemical Engineering Journal
◽
10.1016/j.cej.2021.134199
◽
2021
◽
pp. 134199
Author(s):
Yayang Xu
◽
Mu Liu
◽
Fengxia Tong
◽
Fahao Ma
◽
Xiangyun He
◽
...
Keyword(s):
Single Particle
◽
Water Gas Shift
◽
Water Gas Shift Reaction
◽
Reverse Water Gas Shift
◽
Shift Reaction
◽
Water Gas
Download Full-text
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