Understanding metal-free catalytic hydrogenation: A systematic theoretical study of the hydrogenation of ethene

Bun Chan; Leo Radom

doi:10.1071/CH04031

Understanding metal-free catalytic hydrogenation: A systematic theoretical study of the hydrogenation of ethene

Bun Chan, Leo Radom^*

^*Corresponding author for this work

Research output: Contribution to journal › Article › peer-review

16 Citations (Scopus)

Abstract

Metal-free catalytic hydrogenation of ethene has been examined using high-level [G3(MP2)-RAD] ab initio molecular orbital theory. The dependence of the catalytic activity on the nature of the catalyst Z - X - H has been explored. We find that the catalytic activity is generally greater as Z-X-H becomes more acidic, both for first- and second-row atoms X. Molecules in which X is a second-row atom generally lead to more effective catalysis than the corresponding first-row analogues. The proton affinity at X of Z-X-H also contributes significantly to the catalysis in some cases (e.g. amines).

Original language	English
Pages (from-to)	659-663
Number of pages	5
Journal	Australian Journal of Chemistry
Volume	57
Issue number	7
DOIs	https://doi.org/10.1071/CH04031
Publication status	Published - 2004

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abstract = "Metal-free catalytic hydrogenation of ethene has been examined using high-level [G3(MP2)-RAD] ab initio molecular orbital theory. The dependence of the catalytic activity on the nature of the catalyst Z - X - H has been explored. We find that the catalytic activity is generally greater as Z-X-H becomes more acidic, both for first- and second-row atoms X. Molecules in which X is a second-row atom generally lead to more effective catalysis than the corresponding first-row analogues. The proton affinity at X of Z-X-H also contributes significantly to the catalysis in some cases (e.g. amines).",

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year = "2004",

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pages = "659--663",

journal = "Australian Journal of Chemistry",

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T1 - Understanding metal-free catalytic hydrogenation

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AU - Radom, Leo

PY - 2004

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AB - Metal-free catalytic hydrogenation of ethene has been examined using high-level [G3(MP2)-RAD] ab initio molecular orbital theory. The dependence of the catalytic activity on the nature of the catalyst Z - X - H has been explored. We find that the catalytic activity is generally greater as Z-X-H becomes more acidic, both for first- and second-row atoms X. Molecules in which X is a second-row atom generally lead to more effective catalysis than the corresponding first-row analogues. The proton affinity at X of Z-X-H also contributes significantly to the catalysis in some cases (e.g. amines).

UR - https://www.scopus.com/pages/publications/3242689077

U2 - 10.1071/CH04031

DO - 10.1071/CH04031

M3 - Article

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SP - 659

EP - 663

JO - Australian Journal of Chemistry

JF - Australian Journal of Chemistry

IS - 7

ER -

Understanding metal-free catalytic hydrogenation: A systematic theoretical study of the hydrogenation of ethene

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