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Rates and reversibility of CO
2
hydrogenation on Cu-based catalysts
Ting C. Lin,
Aditya Bhan
Chemical Engineering and Materials Science
Research output
:
Contribution to journal
›
Article
›
peer-review
7
Scopus citations
Overview
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2
hydrogenation on Cu-based catalysts'. Together they form a unique fingerprint.
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Keyphrases
CO2 Hydrogenation
100%
Methanol Synthesis
100%
Cu-based Catalyst
100%
Reverse Water Gas Shift
80%
Methanol Yield
60%
Methanol Selectivity
60%
In Situ
40%
Reaction Kinetics
40%
Forward Rate
40%
Active Site Density
40%
Cu-ZnO-Al2O3
40%
Methanol Gasoline
20%
Systems Approach
20%
Far-from-equilibrium
20%
Thermodynamics
20%
Kinetic Analysis
20%
CO2 Conversion
20%
Reaction Pathway
20%
First-order
20%
Steady-state Kinetics
20%
Observed Trends
20%
Kinetic Measurements
20%
Equilibrium Constraints
20%
Thermodynamic Constraints
20%
Intrinsic Rate of Increase
20%
Chemical Titration
20%
Chlorine
20%
Added Water
20%
Mathematical Formalism
20%
Sorption Enhanced
20%
H2 Partial Pressure
20%
Kinetic Treatment
20%
Hydrogen Pressure
20%
Cu-ZnO-Al2O3 Catalysts
20%
Water Adsorbent
20%
Chemical Engineering
Hydrogenation
100%
Carbon Dioxide
100%
Methanol
83%
Methanol Synthesis
83%
Water-Gas Shift
66%
Material Science
Hydrogenation
100%
Carbon Dioxide
100%
ZnO
50%
Al2O3
50%
Density
33%
Catalysis
16%