张旭

个人信息Personal Information


学历:博士研究生毕业

学位:工学博士学位

性别:

学科:力学. 航空宇航科学与技术. 材料科学与工程. 机械工程. 冶金工程. 先进制造. 航空工程. 材料工程. 冶金工程. 机械工程. 固体力学

多尺度与微纳米力学,梯度结构材料,界面力学,固体本构关系,应变梯度理论,晶体塑性有限元,离散位错动力学,分子动力学,高熵合金,大数据与机器学习,材料基因,极端力学,高性能材料

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2022

当前位置: 多尺度材料力学 >> 团队新闻 >> 2022

2022-09-05 博士生陆宋江论文“Synergetic-Deformation-Induced Strengthening in Gradient Nano-Grained Metals: A 3D Discrete Dislocation Dynamics Study”在Metals专刊“Advances in High Strength–Ductility Synergy Materials”发表

Abstract

Gradient nano-grained (GNG) metals have shown high synergetic strength and good ductility due to their unique gradient microstructure. In this study, the mechanical behavior of gradient nano-grained metals was investigated by three-dimensional discrete dislocation dynamics. The simulation results show a trend that the successive yielding and gradual “transmission” of dislocations along the gradient direction result in a gradient distribution of stress and plastic strain. The distribution of geometrically necessary dislocations is more inhomogeneous in the gradient nano-grained (GNG) sample compared with those homogenous counterparts. The non-uniform deformation response of component layers induces the synergetic-deformation-induced (SDI) strengthening in the GNG sample. The back stress originates from geometrically necessary dislocations that pile up near the interface of gradient layers and leads to a significant hardening while there is a slight softening in different gradient layers in the GNG sample. This study provides a deeper insight into the SDI strengthening in gradient structure from the submicron scale


Link

https://www.researchgate.net/publication/363340345_Synergetic-Deformation-Induced_Strengthening_in_Gradient_Nano-Grained_Metals_A_3D_Discrete_Dislocation_Dynamics_Study