DFT transition state study of the catalyzed oxidation of methane on SnO2 surfaces

IF 5.2 2区化学 Q1 CHEMISTRY, APPLIED

Catalysis Today Pub Date : 2022-06-01 DOI:10.1016/j.cattod.2021.09.037

E. Valdez García , G. Carbajal-Franco , O.A. López-Galán

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引用次数: 7

Abstract

Along this research the (110), (101) (200) and (211) surfaces were chosen to be studied by considering their atomic surface density. The surfaces were studied using CASTEP for the transition state search by DFT calculations, the initial coordinates that establish the SnO₂-Methane distance were obtained with Adsorption Locator, a software able to calculate adsorption configurations using Monte Carlo methods. The results show that in terms of overall energy change, surface (101) presents the most favorable configuration with an exothermic total-energy change (form CH₄ on the surface to a CO and H₂O molecules on the surface) of − 18.47 kcal/mol, being the worst case the CH₄ on a (200) surface with an endothermic total energy-change of 128.86 kcal/mol. In terms of the TS energy, the (101) surface remains as the most favorable system with energy maximums on the TS reaction path of 99.25 kcal/mol for the dissociation and adsorption of the CH₄ molecule on the surface, and a maximum of 266.42 kcal/mol for the desorption and formation of the CH₄ and H₂O molecules on the SnO₂ surface.

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SnO2表面甲烷催化氧化的DFT过渡态研究

在本研究中，考虑到(110)、(101)、(200)和(211)表面的原子表面密度，选择了它们作为研究对象。采用CASTEP进行过渡态搜索，通过DFT计算对表面进行研究，利用吸附定位器(一种能够使用蒙特卡罗方法计算吸附构型的软件)获得建立sno2 -甲烷距离的初始坐标。结果表明，在总能量变化方面，表面(101)表现出最有利的构型，其放热总能量变化(从表面的CH4转变为表面的CO和H2O分子)为- 18.47 kcal/mol，而表面(200)CH4表现最差，其吸热总能量变化为128.86 kcal/mol。在TS能量方面，(101)表面仍然是最有利的体系，其TS反应路径上CH4分子在表面的解离和吸附能量最大值为99.25 kcal/mol, CH4和H2O分子在SnO2表面的解吸和形成能量最大值为266.42 kcal/mol。

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来源期刊

Catalysis Today 化学-工程：化工

CiteScore

11.50

自引率

3.80%

发文量

573

审稿时长

2.9 months

期刊介绍： Catalysis Today focuses on the rapid publication of original invited papers devoted to currently important topics in catalysis and related subjects. The journal only publishes special issues (Proposing a Catalysis Today Special Issue), each of which is supervised by Guest Editors who recruit individual papers and oversee the peer review process. Catalysis Today offers researchers in the field of catalysis in-depth overviews of topical issues. Both fundamental and applied aspects of catalysis are covered. Subjects such as catalysis of immobilized organometallic and biocatalytic systems are welcome. Subjects related to catalysis such as experimental techniques, adsorption, process technology, synthesis, in situ characterization, computational, theoretical modeling, imaging and others are included if there is a clear relationship to catalysis.