单层
密度泛函理论
吸附
甲烷
化学物理
结合能
费米能级
离子键合
材料科学
粘结长度
基质(水族馆)
轨道杂交
化学
计算化学
纳米技术
物理化学
结晶学
分子轨道
分子
原子物理学
离子
分子轨道理论
物理
有机化学
晶体结构
海洋学
地质学
电子
量子力学
作者
Alexandra B. Santos-Putungan,Darwin Barayang Putungan
标识
DOI:10.1088/2053-1591/ab104d
摘要
In this work, the adsorption mechanism of methane on strained 1T'-MoS2 monolayer was investigated using density functional theory calculations. Motivated by a recent finding on the role of strained 1T'-MX2 transition metal dichalcogenide monolayers on hydrogen evolution reaction (Putungan et al 2015 Phys. Chem. Chem. Phys. 17, 21702–21708), we probed methanes's binding properties on three selected sites: S1 (elongated bond lengths with Mo), S2 (shortened bond lengths with Mo) and Mo Top . It is found that methane does not bind with S1 and S2, but rather adsorbs on Mo Top with relatively weak adsorption energy. Application of isotropic tensile biaxial strain tend to improve methane's adsorption, but not until a seemingly 'turn on' strain is reached (at 10%) that a significant increase in the binding energy is reached. It is suggested that strain reinforces states in the vicinity of the Fermi level, thereby improving states hybridization leading to better adsorbate-substrate interaction. Furthermore, strain helps enhance charge transfer from 1T'-MoS2 to methane, improving ionic interaction between the two. These results and insights are of significance in the design of future devices for methane sequestration, storage and release that can be controlled and fine-tuned using strain.
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