密度涨落作为拥挤表面上扩散的开启者。

Density fluctuations as door-opener for diffusion on crowded surfaces.

作者信息

Henß Ann-Kathrin, Sakong Sung, Messer Philipp K, Wiechers Joachim, Schuster Rolf, Lamb Don C, Groß Axel, Wintterlin Joost

机构信息

Department of Chemistry, Ludwig-Maximilians-Universität München, Germany.

Institute of Theoretical Chemistry, University of Ulm, Ulm, Germany.

出版信息

Science. 2019 Feb 15;363(6428):715-718. doi: 10.1126/science.aav4143. Epub 2019 Feb 14.

DOI:10.1126/science.aav4143

PMID:30765561

Abstract

How particles can move on a catalyst surface that, under the conditions of an industrial process, is highly covered by adsorbates and where most adsorption sites are occupied has remained an open question. We have studied the diffusion of O atoms on a fully CO-covered Ru(0001) surface by means of high-speed/variable-temperature scanning tunneling microscopy combined with density functional theory calculations. Atomically resolved trajectories show a surprisingly fast diffusion of the O atoms, almost as fast as on the clean surface. This finding can be explained by a "door-opening" mechanism in which local density fluctuations in the CO layer intermittently create diffusion pathways on which the O atoms can move with low activation energy.

摘要

在工业过程条件下，催化剂表面被吸附物高度覆盖且大多数吸附位点被占据时，粒子如何在其上移动仍是一个悬而未决的问题。我们通过高速/可变温度扫描隧道显微镜结合密度泛函理论计算，研究了O原子在完全被CO覆盖的Ru(0001)表面上的扩散。原子分辨轨迹显示O原子的扩散速度惊人地快，几乎与在清洁表面上一样快。这一发现可以用“开门”机制来解释，即CO层中的局部密度涨落间歇性地创造出扩散路径，O原子可以在这些路径上以低活化能移动。

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密度涨落作为拥挤表面上扩散的开启者。

Density fluctuations as door-opener for diffusion on crowded surfaces.

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密度涨落作为拥挤表面上扩散的开启者。

Density fluctuations as door-opener for diffusion on crowded surfaces.

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出版信息

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