Direct versus hydrogen-assisted CO dissociation

S.G. Shetty; A.P.J. Jansen; R.A. Santen, van

doi:10.1021/ja9044482

Direct versus hydrogen-assisted CO dissociation

S.G. Shetty
, A.P.J. Jansen
, R.A. Santen, van

Inorganic Materials & Catalysis

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

179 Citations (Scopus)

Abstract

(Graph Presented) The mechanism of CO dissociation is a fundamental issue in the technologically important Fischer-Tropsch (F-T) process that converts synthesis gas into liquid hydrocarbons. In the present study, we propose that on a corrugated Ru surface consisting of active sixfold (i.e., fourfold + twofold) sites, direct CO dissociation has a substantially lower barrier than the hydrogen-assisted paths (i.e., via HCO or COH intermediates). This proves that the F-T process on corrugated Ru surfaces and nanoparticles with active sixfold sites initiates through direct CO dissociation instead of hydrogenated intermediates.

Original language	English
Pages (from-to)	12874-12875
Journal	Journal of the American Chemical Society
Volume	131
Issue number	36
DOIs	https://doi.org/10.1021/ja9044482
Publication status	Published - 2009

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10.1021/ja9044482

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abstract = "(Graph Presented) The mechanism of CO dissociation is a fundamental issue in the technologically important Fischer-Tropsch (F-T) process that converts synthesis gas into liquid hydrocarbons. In the present study, we propose that on a corrugated Ru surface consisting of active sixfold (i.e., fourfold + twofold) sites, direct CO dissociation has a substantially lower barrier than the hydrogen-assisted paths (i.e., via HCO or COH intermediates). This proves that the F-T process on corrugated Ru surfaces and nanoparticles with active sixfold sites initiates through direct CO dissociation instead of hydrogenated intermediates.",

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AB - (Graph Presented) The mechanism of CO dissociation is a fundamental issue in the technologically important Fischer-Tropsch (F-T) process that converts synthesis gas into liquid hydrocarbons. In the present study, we propose that on a corrugated Ru surface consisting of active sixfold (i.e., fourfold + twofold) sites, direct CO dissociation has a substantially lower barrier than the hydrogen-assisted paths (i.e., via HCO or COH intermediates). This proves that the F-T process on corrugated Ru surfaces and nanoparticles with active sixfold sites initiates through direct CO dissociation instead of hydrogenated intermediates.

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Direct versus hydrogen-assisted CO dissociation

Abstract

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