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引用次数: 6
摘要
本文概述了Baowan等人(2007)开发的两种最小二乘方法,用于平面石墨烯片与碳纳米管的垂直连接。两种最小二乘方法分别是键长变化和键角变化。这些被用来检查锯齿形(8,0)碳纳米管与扁平石墨烯片的连接结构。与(8,0)管开口端的原子数相对应,有16种可能的不同缺陷,因此,总共有16种连接结构需要研究。此外,还确定了出现在交接处的多边形,并证明了它们与欧拉塞拉斯定理是一致的。假设只有五边形、六边形和七边形是可以接受的,那么可能的结构数量就大大减少了,但只有一种结构在物理上是有意义的。这些纯粹的几何方法可以与一些作者使用的某种数值能量最小化方法直接相关(Cornell et al., 1995)。
This paper is a synopsis of the two least squares approaches developed in the work of Baowan et al. (2007) for the perpendicular joining of a flat graphene sheet with a carbon nanotube. The two least squares approaches are the variation in the bond length and the variation in the bond angle. These are used to examine the joined structure of a zigzag (8,0) carbon nanotube with a flat graphene sheet. There are sixteen possible distinct defects corresponding to the number of atoms at the (8,0) tube open end, and therefore, in total sixteen joining structures need to be investigated. Moreover, the polygons that occur at the junction are determined and are shown to be consistent with Eulerpsilas theorem. Assuming that only pentagons, hexagons and heptagons are acceptable, the number of possible structures is greatly reduced, but there is only one structure that is physically meaningful. These purely geometrical approaches can be formally related directly to a certain numerical energy minimization method used by a number of authors (Cornell et al., 1995).
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