A DFT-D investigation of the energetic and structural aspects of dehydrogenation of methanol on a bimetallic surface PtGe(110) exploring the germanium effect on the anti-poisoning of pt(110) catalytic activity

Q3 Biochemistry, Genetics and Molecular Biology
Abdellatif Hassak, R. Ghailane
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Abstract

Platinum is the most active pure metal for dehydrogenating methanol to create hydrogen, which is crucial for fuel cells. However, one significant disadvantage that reduces the effectiveness and long-term performance of platinum catalysts is their susceptibility to CO poisoning. In the current study, we examine and elucidate the promotional impact of Ge on Pt catalysts with increased resistance to deactivation by CO poisoning. We do this by combining partial density of states calculations with electronic configuration and Mulliken atomic charges. The self-consistent periodic density functional theory with dispersion correction (DFT-D) was used to investigate the methanol adsorption and dehydrogenation mechanisms on the surface of PtGe (110). On the surface, several adsorption mechanisms of pertinent intermediates were found. Furthermore, a thorough analysis of a reaction network comprising four reaction paths revealed that, in terms of activation barriers, the first O—H bond scission of CH3OH appears to be more advantageous than C—H bond cleavage on the PtGe(110) surface. Additionally, it has been demonstrated that the main route on the PtGe(110) surface is CH3OH→CH3O→CH2O→CHO→CO evolution. The remarkable differences in the predominant reaction pathway on the Pt(110) surface, and PtGe(110) surface indicate that the Ge-doped Pt Nano catalyst is more selective and resistant to deactivation.
双金属表面 PtGe(110)上甲醇脱氢的能量和结构方面的 DFT-D 研究,探索锗对 pt(110)催化活性的抗中毒效应
铂是最活跃的纯金属,可用于甲醇脱氢产生氢气,这对燃料电池至关重要。然而,铂催化剂的一个显著缺点是容易受到 CO 的毒害,这降低了铂催化剂的有效性和长期性能。在当前的研究中,我们研究并阐明了 Ge 对铂催化剂的促进作用,这种催化剂具有更强的抗 CO 中毒失活能力。为此,我们将部分态密度计算与电子构型和 Mulliken 原子电荷相结合。我们使用自洽周期密度泛函理论与弥散校正(DFT-D)研究了 PtGe (110) 表面的甲醇吸附和脱氢机制。研究发现了铂锗表面相关中间产物的几种吸附机理。此外,对包括四种反应路径的反应网络进行的深入分析显示,就活化障碍而言,CH3OH 的第一个 O-H 键裂解似乎比 PtGe(110) 表面上的 C-H 键裂解更有利。此外,研究还证明,PtGe(110) 表面上的主要途径是 CH3OH→CH3O→CH2O→CHO→CO 演化。铂(110)表面和铂锗(110)表面的主要反应途径存在明显差异,这表明掺锗铂纳米催化剂的选择性和抗失活能力更强。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
Turkish Computational and Theoretical Chemistry
Turkish Computational and Theoretical Chemistry Biochemistry, Genetics and Molecular Biology-Biochemistry, Genetics and Molecular Biology (miscellaneous)
CiteScore
2.40
自引率
0.00%
发文量
4
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