Lowering the C-H Bond Activation Barrier of Methane Using SAC@Cu(111): A Periodic DFT Investigations

ChemRxiv : the preprint server for chemistry Pub Date : 2021-09-23 DOI:10.33774/chemrxiv-2021-zfrcn

M. Bhati, J. Dhumal, Kavita Joshi

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Abstract

Methane has long captured the world's spotlight for being the simplest and yet one of the most notorious hydrocarbon. Exploring its potential to be converted into value added products has raised a compelling interest. In the present work, we have studied the efficiency of Single-Atom Catalysts (SACs) for methane activation employing Density Functional Theory (DFT). The Climbing Image-Nudged Elastic Bond (CI-NEB) method is used in tandem with the Improved Dimer (ID) method to determine the minimum energy pathway for the first C-H bond dissociation of methane. Our study reported that the transition-metal doped Cu(111) surfaces enhance adsorption, activate C-H bond, and reduce activation barrier for first C-H bond cleavage of methane. The results suggest Ru/Co/Rh doped Cu(111) as promising candidates for methane activation with minimal activation barrier and less endothermic reaction. For these SACs, the calculated activation barriers for first C-H bond cleavage are 0.17 eV, 0.24 eV, and 0.26 eV respectively, which is substantially lower than 1.13 eV, the activation barrier for Cu(111).

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利用SAC@Cu(111)降低甲烷C-H键激活势垒:周期性DFT研究

长期以来，甲烷一直是世界关注的焦点，因为它是最简单的，但也是最臭名昭著的碳氢化合物之一。探索其转化为增值产品的潜力引起了人们的强烈兴趣。本文采用密度泛函理论(DFT)研究了单原子催化剂(SACs)的甲烷活化效率。采用爬升图像推动弹性键(CI-NEB)方法和改进二聚体(ID)方法，确定了甲烷第一碳氢键解离的最小能量途径。我们的研究报道了过渡金属掺杂Cu(111)表面增强了甲烷的吸附，激活了C-H键，降低了第一C-H键裂解的激活垒。结果表明，Ru/Co/Rh掺杂Cu(111)具有最小的活化屏障和较少的吸热反应，是甲烷活化的理想候选材料。对于这些SACs，计算出的第一C-H键裂解的激活势垒分别为0.17 eV、0.24 eV和0.26 eV，大大低于Cu的激活势垒1.13 eV(111)。

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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