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典型文献
Mechanical behavior of single-layer graphdiyne via supersonic micro-projectile impact
文献摘要:
The mechanical behavior of single-layer graphdiyne(SLGDY)subjected to high-velocity micro-ballistic impacts is analyzed by molecular dynamics(MD)simulations.The ballistic limits of SLGDY is obtained for the first time.The temperature deterioration effects of the impact resistance are also investigated.The results show that the ballistic limits can reach 75.4%of single-layer graphene(SLGR)at about 1/2 density,leading to approximately the same specific energy absorption(SEA)as SLGR.The ballistic limits of SLGDY and SLGR with single atomic thickness agree with the predictions of macroscopic penetration limits equations,implying the applicability of continuum penetration theories for two-dimensional(2D)materials.In addition,the dynamic responses involving stress wave propagation,conic deformation,and damage evolution are investigated to illuminate the mechanisms of the dynamic energy dissipation.The superior impact resistance of SLGDY and SLGR can be attributed to both the ultra-fast elastic and conic waves and the excellent deformation capabilities.This study provides a deep under-standing of the impact behavior of SLGDY,indicating it is a promising protective material.
文献关键词:
中图分类号:
[1] 医药、卫生(R) / 基础医学(R3) / 病理学(R36) / 病理过程(R364)
[2] 医药、卫生(R) / 神经病学与精神病学(R74) / 神经病学(R741)
[3] 经济(F) / 工业经济(F4) / 中国工业经济(F42)
作者姓名:
Kailu Xiao;Qiuyun Yin;Xianqian Wu;Chenguang Huang
作者机构:
Institute of Mechanics,Chinese Academy of Sciences,Beijing,100190,China;School of Engineering Science,University of Chinese Academy of Sciences,Beijing,100049,China;Department of Applied Mechanics&Engineering,School of Engineering,Sun Yat-sen University,Guangzhou,510275,China;School of Aerospace Engineering,Xi'an Jiaotong University,Xi'an,710049,China;Hefei Institutes of Physical Science,Chinese Academy of Sciences,Heifei,230031,China
文献出处:
纳米材料科学(英文版)
引用格式:
[1]Kailu Xiao;Qiuyun Yin;Xianqian Wu;Chenguang Huang-.Mechanical behavior of single-layer graphdiyne via supersonic micro-projectile impact)[J].纳米材料科学(英文版),2022(04):383-392
A类:
SLGDY,SLGR
B类:
Mechanical,behavior,single,layer,graphdiyne,via,supersonic,micro,projectile,mechanical,subjected,high,velocity,ballistic,impacts,analyzed,by,molecular,dynamics,MD,simulations,limits,obtained,first,temperature,deterioration,effects,resistance,are,also,investigated,results,show,that,can,reach,graphene,about,density,leading,approximately,same,specific,energy,absorption,SEA,atomic,thickness,agree,predictions,macroscopic,penetration,equations,implying,applicability,continuum,theories,two,dimensional,2D,materials,In,addition,responses,involving,stress,propagation,conic,deformation,damage,evolution,illuminate,mechanisms,dissipation,superior,attributed,both,ultra,fast,elastic,waves,excellent,capabilities,This,study,provides,deep,under,standing,indicating,promising,protective
AB值:
0.54537
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