期刊
CARBON
卷 171, 期 -, 页码 96-103出版社
PERGAMON-ELSEVIER SCIENCE LTD
DOI: 10.1016/j.carbon.2020.08.082
关键词
Cyclo[18]carbon; Mechanical properties; Tension; Expansion; Energy gap
资金
- National Science Foundation [CMMI-1661699]
- ACS Petroleum Research Fund [PRF-60329-ND10]
Recent atomic manipulation using an AFM tip has led to the creation of the first sp-hybridized carbon material, cyclo[18] carbon. This material shows unique mechanical properties, such as ultra-elastic behavior, small Young's modulus, and specific tensile stiffness, making it a potential candidate for use in nanomechanical systems and molecular electronics.
Recent atomic manipulation by an AFM tip created the first sp-hybridized carbon material - cyclo[18] carbon. Herein, we revealed the unique mechanical properties of cyclo[18]carbon by the first principle calculations. Under uniaxial tension, cyclo[18]carbon is ultra-elastic as demonstrated by a small Young's modulus of 0.11 TPa and a tiny specific tensile stiffness of 7.0 x 10(6) N m/kg, which are one and two orders of magnitude smaller than those of other carbon materials, respectively. The expansion and contraction of cyclo[18]carbon exhibit a relatively high specific stiffness of 9.95 x 10(8) N m/kg, and it would be broken with an energy requirement of 34.14 eV. While uniaxial tension enables the insulator-semiconductor transition of cyclo[18]carbon, expansion enlarges its energy gap. Furthermore, the strain energy was proposed as a function of bond angle and bond length for uniaxially-stretched and expanded/contracted cyclo[18]carbon respectively, which sheds light on predicting the mechanical properties of certain materials. The unique properties of cyclo[18]carbon are of great interest for its potential use as an ultraelastic molecular O-ring in nanomechanical system and molecular electronics and devices. (C) 2020 Elsevier Ltd. All rights reserved.
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