Yang Meng, Haiyan Wang, Jin-Xia Liang*, Chun Zhu* and Jun Li*,
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引用次数: 0
摘要
单原子催化剂(SAC)为阐明异相催化中复杂反应的催化机理提供了机会。低温水气变换(WGS)反应是获得高纯度氢气的一项重要工业技术。在此,我们利用密度泛函理论(DFT)研究了 Pt1@Ti3C2T2 (T = O, S) SACs 的催化活性,其中在功能化的 Ti3C2T2 (T = O, S) MXene 中,一个具有三个 T 空位的亚表面 Ti 原子被一个 Pt 原子取代,用于低温 WGS 反应。结果表明,Pt1@Ti3C2T2 的碗状空位来自于 Pt1 单原子及其周围的三个 T 缺陷,为 WGS 反应提供了一个极好的平台。特别是,Pt1@Ti3C2S2 SAC 对 WGS 反应具有更高的催化性能,这是由于 S 原子的电负性弱于 O 原子,这大大降低了 WGS 反应中 H* 迁移的能量障碍,而 H* 迁移往往是决定速率的一步。在 Pt1@Ti3C2S2 上最有利的 WGS 反应氧化还原机理中,决定速率的步骤是 OH* 离解为 O* 和 H*,能垒低至 1.12 eV。这些结果表明,Pt1@Ti3C2S2 在应用 MXenes 进行低温 WGS 反应方面大有可为。
Computational Screening of Pt1@Ti3C2T2 (T = O, S) MXene Catalysts for Water–Gas Shift Reaction
Single-atom catalysts (SACs) provide an opportunity to elucidate the catalytic mechanism of complex reactions in heterogeneous catalysis. The low-temperature water–gas shift (WGS) reaction is an important industrial technology to obtain high purity hydrogen. Herein, we study the catalytic activity of Pt1@Ti3C2T2 (T = O, S) SACs, where one subsurface Ti atom with three T vacancies in the functionalized Ti3C2T2 (T = O, S) MXene is substituted by one Pt atom, for the low-temperature WGS reaction, using density functional theory (DFT). The results show that Pt1@Ti3C2T2 provides an excellent platform for the WGS reaction by its bowl-shaped vacancy derived from the Pt1 single atom and three T defects surrounding it. Especially, Pt1@Ti3C2S2 SAC has higher catalytic performance for the WGS reaction, due to the weaker electronegativity of the S atom than the O atom, which significantly reduces the energy barrier of H* migration in the WGS reaction, which is often the rate-determining step. In the most favorable redox mechanism of the WGS reaction on Pt1@Ti3C2S2, the rate-determining step is the dissociation of OH* into O* and H* with the energy barrier as low as 1.12 eV. These results demonstrate that Pt1@Ti3C2S2 is promising in the application of MXenes for low-temperature WGS reactions.
期刊介绍:
Chemical research focused on precision enables more controllable predictable and accurate outcomes which in turn drive innovation in measurement science sustainable materials information materials personalized medicines energy environmental science and countless other fields requiring chemical insights.Precision Chemistry provides a unique and highly focused publishing venue for fundamental applied and interdisciplinary research aiming to achieve precision calculation design synthesis manipulation measurement and manufacturing. It is committed to bringing together researchers from across the chemical sciences and the related scientific areas to showcase original research and critical reviews of exceptional quality significance and interest to the broad chemistry and scientific community.
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