期刊
CARBON
卷 191, 期 -, 页码 98-105出版社
PERGAMON-ELSEVIER SCIENCE LTD
DOI: 10.1016/j.carbon.2022.01.040
关键词
alpha-graphyne nanoscroll; Brittle-ductile transition; Temperature; Micromechanism
资金
- NSFC [12032004, 11872114, 11502150]
- Natural Science Foundation of Hebei Province of China [A2016210060]
- Higher Education Youth Talents Program of Hebei Province of China [BJ2017052]
This study systematically investigates the tensile mechanical properties of a one-dimensional carbon nanomaterial and reveals a brittle-ductile transition at different temperatures. The results show that the microstructures play a crucial role in the plastic behavior of the material, and the introduction of interlayer bonds can improve its ductility.
One-dimensional (1D) carbon nanomaterials are usually stiff, strong, and brittle. In this study, the tensile mechanical properties of alpha-graphyne nanoscroll (alpha-GNS) at different temperatures were systematically investigated using the reactive molecular dynamics method. It was found that the alpha-GNS could undergo a brittle-ductile transition as the temperature increased from 100 K to 1000 K. When the temperature was below the critical brittle-ductile transition temperature (BDTT) of similar to 375 K, the alpha-GNS exhibited brittle behavior; however, when the temperature was above the BDTT, it exhibited ductile behavior. Dynamic analyses demonstrated that the superplastic behavior was influenced by two typical microstructures: intralayer carbon triatomic rings and interlayer carbon bonds. NEB (nudged elastic band) calculations further showed that the intralayer triatomic rings can promote plastic deformation, while the interlayer bonds retard plastic deformation by increasing the energy barrier of formation of intralayer triatomic rings. However, alpha-GNSs can also be made to exhibit good ductile behavior below the BDTT by introducing interlayer bonds using high-temperature annealing technology, which is mainly due to the postponed crack propagation in alpha-GNSs. This study could be beneficial for the design of novel 1D carbon nano-materials with controllable brittleness and ductility. (C) 2022 Elsevier Ltd. All rights reserved.
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