【摘 要】
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Our recently developed atomistic-continuum multiscale approach based on the higher-order Cauchy-Bom rule has demonstrated outstanding performance in terms of computational stability and accuracy.With
【机 构】
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产品包装与物流广东普通高校重点实验室,珠海,暨南大学 中国科学院材料力学行为和设计重点实验室,合肥
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Our recently developed atomistic-continuum multiscale approach based on the higher-order Cauchy-Bom rule has demonstrated outstanding performance in terms of computational stability and accuracy.With the help of a mesh-free computational framework on the basis of the moving Kriging interpolation, the commonly encountered essential boundary condition problems and singular matrix problems can be easily solved.By iteratively updating the system stiffness matrix and the residual stress, this approach can provide a good prediction for the real deformation pattern of carbon-based nanostructures as compared with conventional atomistic simulation.This multiscale approach has been successfully applied to predict the buckling behaviors of carbon nanotubes/carbon nanocones and the nonlinear bending deflection of graphene.It is also suitable to control the surface morphology of carbon-based nano devices, such as the wrinkle patterns of graphene can be tuned by imposing a twisting load.
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