A Computational Characterization of CH4@C60

Inorganics Pub Date : 2024-02-21 DOI:10.3390/inorganics12030064

Z. Slanina, F. Uhlík, Takeshi Akasaka, Xing Lu, L. Adamowicz

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Abstract

The recently synthetically prepared endohedral CH4@C60 was characterized here using calculations—namely its structure, energetics, thermodynamics, and vibrational spectrum. The calculations were carried out with DFT (density-functional theory) methods, namely by the DFT M06-2X functional and MP2, as well as B2PLYPD advanced correlated, treatments with the standard 6-31++G** and 6-311++G** basis sets, corrected for the basis set superposition error evaluated using the approximative Boys–Bernardi counterpoise method. The symmetry of the endohedral obtained in the geometry optimizations was tetrahedral T. The energetics of CH4 encapsulation into C60 was attractive (i.e., with a negative encapsulation-energy term), producing a substantial energy gain of −13.94 kcal/mol at the most advanced computational level, B2PLYPD/6-311++G**. The encapsulation equilibrium constants for CH4@C60 were somewhat higher than previously found with the CO@C60 system. For example at 500 K, the encapsulation equilibrium constant for CH4@C60 had a value one order of magnitude larger than for CO@C60. The encapsulation thermodynamic characteristics suggest that high-pressure and high-temperature synthesis could in principle also be possible for CH4@C60.

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CH4@C60 的计算特征

本文通过计算，即其结构、能量学、热力学和振动光谱，对最近合成制备的内面体 CH4@C60 进行了表征。计算采用了 DFT（密度泛函理论）方法，即 DFT M06-2X 函数和 MP2，以及 B2PLYPD 高级相关方法，使用标准 6-31++G** 和 6-311++G** 基集进行处理，并使用近似 Boys-Bernardi 反极值方法对基集叠加误差进行了修正。在几何优化中获得的内面体对称性为四面体 T。C60 中封装 CH4 的能量具有吸引力（即封装能量为负项），在最先进的计算水平 B2PLYPD/6-311++G** 中产生了 -13.94 kcal/mol 的巨大能量增益。CH4@C60 的封装平衡常数略高于之前发现的 CO@C60 系统。例如，在 500 K 时，CH4@C60 的封装平衡常数比 CO@C60 大一个数量级。封装热力学特性表明，CH4@C60 原则上也可以进行高压和高温合成。

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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Inorganics

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