Department of Civil Engineering, National University of Singapore, Singapore.
J Phys Condens Matter. 2010 Sep 1;22(34):345301. doi: 10.1088/0953-8984/22/34/345301. Epub 2010 Aug 2.
Owing to their remarkable mechanical properties, carbon nanotubes have been employed in many diverse areas of applications. However, similar to any of the many man-made materials used today, carbon nanotubes (CNTs) are also susceptible to various kinds of defects. Understanding the effect of defects on the mechanical properties and behavior of CNTs is essential in the design of nanotube-based devices and composites. It has been found in various past studies that these defects can considerably affect the tensile strength and fracture of CNTs. Comprehensive studies on the effect of defects on the buckling and vibration of nanotubes is however lacking in the literature. In this paper, the effects of various configurations of atomic vacancy defects, on axial buckling of single-walled carbon nanotubes (SWCNTs), in different thermal environments, is investigated using molecular dynamics simulations (MDS), based on a COMPASS force field. Our findings revealed that even a single missing atom can cause a significant reduction in the critical buckling strain and load of SWCNTs. In general, increasing the number of missing atoms, asymmetry of vacancy configurations and asymmetric distribution of vacancy clusters seemed to lead to higher deterioration in buckling properties. Further, SWCNTs with a single vacancy cluster, compared to SWCNTs with two or more vacancy clusters having the same number of missing atoms, appeared to cause higher deterioration of buckling properties. However, exceptions from the above mentioned trends could be expected due to chemical instabilities of defects. Temperature appeared to have less effect on defective CNTs compared to pristine CNTs.
由于其出色的机械性能,碳纳米管已被应用于许多不同的领域。然而,与当今使用的许多人造材料一样,碳纳米管(CNT)也容易出现各种缺陷。了解缺陷对碳纳米管机械性能和行为的影响,对于基于纳米管的器件和复合材料的设计至关重要。在过去的各种研究中发现,这些缺陷会对碳纳米管的拉伸强度和断裂产生相当大的影响。然而,在文献中缺乏对缺陷对纳米管屈曲和振动影响的综合研究。在本文中,使用基于 COMPASS 力场的分子动力学模拟(MDS)研究了不同热环境下各种原子空位缺陷构型对单壁碳纳米管(SWCNT)轴向屈曲的影响。我们的研究结果表明,即使单个缺失原子也会导致 SWCNT 的临界屈曲应变和载荷显著降低。一般来说,缺失原子数量的增加、空位构型的不对称性以及空位团簇的不对称分布似乎会导致屈曲性能的恶化。此外,与具有相同缺失原子数的两个或更多空位团簇的 SWCNT 相比,具有单个空位团簇的 SWCNT 似乎会导致屈曲性能的更大恶化。然而,由于缺陷的化学不稳定性,可能会出现上述趋势的例外情况。与原始 CNT 相比,温度对缺陷 CNT 的影响较小。