Nanomechanical Behavior of Pentagraphyne-Based Single-Layer and Nanotubes through Reactive Classical Molecular Dynamics

C Pub Date : 2023-06-12 DOI:10.3390/c9040110

José Moreira de Sousa, W. Brandão, Weverson Lucas Aguiar Paula Silva, L. A. Ribeiro Júnior, Douglas Soares Galvão, M. L. Pereira Júnior

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Abstract

A novel 2D carbon allotrope, pentagraphyne (PG-yne), was introduced in a recent theoretical study. This unique structure is derived from pentagraphene by incorporating acetylenic linkages between sp3 and sp2 hybridized carbon atoms. Given its intriguing electronic and structural properties, it is imperative to investigate the mechanical characteristics and thermal responses of PG-yne in both monolayer and nanotube configurations, which encompass different chiralities and diameters. We conducted fully atomistic reactive molecular dynamics (MD) simulations employing the ReaxFF potential to address these aspects. Our findings reveal that Young’s modulus of PG-yne monolayers stands at approximately 51 GPa at room temperature. In contrast, for the studied nanotubes, regardless of their chirality, it hovers around 45 GPa. Furthermore, our observations indicate that PG-yne-based systems feature an extensive and relatively flat plastic region before reaching the point of total fracture, irrespective of their topology. Regarding their thermal properties, we identified a melting point at approximately 3600 K, accompanied by a phase transition around 1100 K.

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通过反应式经典分子动力学研究五苯基单层和纳米管的纳米力学行为

最近的一项理论研究提出了一种新型二维碳同素异形体--五竹烯（PG-yne）。这种独特的结构是通过在 sp3 和 sp2 杂化碳原子之间加入乙炔连接而从五竹烯衍生出来的。鉴于其引人入胜的电子和结构特性，研究 PG-yne 在单层和纳米管构型（包括不同手性和直径）中的机械特性和热反应势在必行。为了解决这些问题，我们采用 ReaxFF 电位进行了全原子反应分子动力学（MD）模拟。我们的研究结果表明，PG-炔单层在室温下的杨氏模量约为 51 GPa。相比之下，对于所研究的纳米管，无论其手性如何，其杨氏模量都徘徊在 45 GPa 左右。此外，我们的观察结果表明，无论拓扑结构如何，基于 PG-yne 的系统在达到完全断裂点之前都有一个广泛且相对平坦的塑性区域。关于它们的热特性，我们发现熔点约为 3600 K，并伴随着 1100 K 左右的相变。

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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