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Cage effects control the mechanism of methane hydroxylation in zeolites
Benjamin E.R. Snyder
, Max L. Bols
, Hannah M. Rhoda
, Dieter Plessers
, Robert A. Schoonheydt
, Bert F. Sels
, Edward I. Solomon
Research output
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peer-review
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Keyphrases
Cage Effect
100%
Zeolite
100%
Effect Control
100%
Methane Hydroxylation
100%
Pore Aperture
80%
Active Sites
60%
Small Pore
40%
Catalytic Cycle
20%
Spectroscopic Characterization
20%
C-H Activation
20%
Density Functional Calculations
20%
Premature Release
20%
Methanol
20%
Reaction Intermediates
20%
Catalytic Conversion
20%
Methane
20%
Single Turnover
20%
Technology-based
20%
Large Pore
20%
Zeolite Pores
20%
Methanol Gasoline
20%
Methane Conversion
20%
Radical Recombination
20%
CH3 Radical
20%
Hindered Diffusion
20%
Biochemistry, Genetics and Molecular Biology
Active Site
100%
Hydroxylation
100%
Facilitated Diffusion
33%
Chemical Engineering
Methanol
100%