Structural Changes of Circularly Defected Monolayer Circular Graphene Nanosheets Upon Mechanical Vibrations

IF 1.5 Q3 MECHANICS
M. Farzannasab, M. M. Khatibi, S. Sadeghzadeh
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引用次数: 1

Abstract

As the strongest and toughest material known, graphene has found numerous applications in various types of sensors. Due to the great influences of the graphene sheet’s geometry on resonance frequency, circular defects could effect on expected results of sensors. Circular holes in circular graphene sheets (CGSs) have been modeled with molecular dynamics (MD) simulation in the present work. Then the vibration behavior of intact circular plate and circular sheet with the circular defect has been investigated using frequency-domain analysis (FDD). Furthermore, for validating the used method, the obtained natural frequencies for different graphene sheets have been compared with acquired data in former research. The result of validation showed the accuracy of the used method in this study. The results indicated that by increasing the hole size, the natural frequency of a defected sheet with free edges will be diminished, and with simply-supported interior boundary conditions typically went up. Also, by increasing the hole’s eccentricity, the natural frequency of the defected graphene sheet will be diminished when the hole boundary was subjected to simply-support or free condition.
圆形缺陷单层圆形石墨烯纳米片在机械振动下的结构变化
作为已知的最强、最坚韧的材料,石墨烯在各种类型的传感器中有着广泛的应用。由于石墨烯片的几何形状对谐振频率有很大影响,圆形缺陷可能会影响传感器的预期结果。本文采用分子动力学(MD)模拟方法对圆形石墨烯片中的圆孔进行了模拟。然后,利用频域分析(FDD)对完整圆板和有圆形缺陷的圆板的振动行为进行了研究。此外,为了验证所使用的方法,将获得的不同石墨烯片的固有频率与先前研究中获得的数据进行了比较。验证结果表明了本研究所用方法的准确性。结果表明,通过增加孔的尺寸,具有自由边缘的缺陷薄板的固有频率将降低,而具有简单支撑的内边界条件通常会增加。此外,通过增加空穴的离心率,当空穴边界受到简单支撑或自由条件时,缺陷石墨烯片的固有频率将降低。
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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来源期刊
CiteScore
1.70
自引率
8.30%
发文量
0
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