王昆 - 湖南大学 - 材料科学与工程学院

个人简介

教育背景 2006-2010年：湖南大学应用物理学专业获理学学士 2010-2015年：湖南大学材料科学与工程学院获工学博士工作履历 2016.06-2018.05：北京应用物理与计算数学研究所计算凝聚态物理国防重点实验室博士后 2018.06-2019.11：北京应用物理与计算数学研究所，助理研究员 2019.12-2020.06：北京应用物理与计算数学研究所，副研究员 2020.07-至今：湖南大学材料科学与工程学院副教授

近期论文

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学术成果 [1] K. Wang*, S. Xiao, J. Chen, S. Yao, W. Hu*, W. Zhu, P. Wang*, F. Gao*, Exploring atomic mechanisms of microstructure evolutions in crystals under vacancy super- or undersaturation states by a kinetic amplitude-expanded phase-field-crystal approach[J]. International Journal of Plasticity, 2022, 157: 103386. [2] P. Li, Y. Huang, K. Wang*, S. Xiao, L. Wang, S. Yao, W. Zhu, W. Hu*, Crystallographic-orientation-dependence plasticity of niobium under shock compressions[J]. International Journal of Plasticity, 2022, 150: 103195. [3] N. Hu, Y. Huang, K. Wang*, W. Hu, W. Zhu, J. Chen, H. Deng*, Roles of triple and quadruple junctions on plasticity by phase-field crystal approach[J]. Physica B: Condensed Matter, 2022, 626: 413449. [4] N. Hu, Y. Huang, K. Wang*, W. Hu, J. Chen, H. Deng*, Solidification of Undercooled Liquid under Supergravity Field by Phase-Field Crystal Approach[J]. Metals, 2022, 12 (2): 232. [5] L. Guo, L. Wang, N. Gao, Y. Chen, B. Liu, W. Hu, S. Xiao, K. Wang, F. Gao*, H. Deng*, Orientation dependence of shock-induced change of habit plane for the 1/2<111> dislocation loop and plasticity in tungsten[J].International Journal of Plasticity, 2022, 155: 103329. [6] B. Liu, Z. Jian, L. Guo, X. Li, K. Wang, H. Deng, W. Hu, S. Xiao*, D. Yuan*, Effect of crystallographic orientations on shock-induced plasticity for CoCrFeMnNi high-entropy alloy[J]. International Journal of Mechanical Sciences, 2022, 226: 107373. [7] 王昆, 肖时芳, 祝文军, 陈军, 胡望宇, 动态载荷下铁相变的原子模拟研究进展[J]. 高压物理学报, 2021, 35 (4): 24. [8] Wang, K., Zhu, W., Xiang, M., Xu, Y., Li, G., Chen, J., 2019. Improved embedded-atom model potentials of Pb at high pressure: application to investigations of plasticity and phase transition under extreme conditions. Modelling and Simulation in Materials Science and Engineering 27, 015001. [9] Wang, K., Zhang, F., He, A., Wang, P., 2019. An atomic view on spall responses of release melted lead induced by decaying shock loading. Journal of Applied Physics 125, 155107. [10] Wang, K., Zhang, F., He, A., Wang, P., 2019. Plasticity and phase transition of crystals under continuous deformations by phase field crystal approach. International Journal of Plasticity 122, 225-243. [11] Li, G., Wang, Y., Wang, K., Xiang, M., Chen, J., 2019. Shock induced plasticity and phase transition in single crystal lead by molecular dynamics simulations. Journal of Applied Physics 126, 075902. [12] Zhang, X., Wang, K., Chen, J., Hu, W., Zhu, W., Xiao, S., Deng, H., Cai, M., 2019. Shock-induced migration of asymmetry tilt grain boundary in iron bicrystal: A case study of Σ3 [110]. Chin. Phys. B 28, 126201-126201. [13] Zhang, X., Wang, K., Zhu, W., Chen, J., Cai, M., Xiao, S., Deng, H., Hu, W., 2018. Effect of grain boundaries on shock-induced phase transformation in iron bicrystals. Journal of Applied Physics 123, 045105. [14] Xiang, M., Liao, Y., Wang, K., Lu, G., Chen, J., 2018. Shock-induced plasticity in semi-coherent {111} Cu-Ni multilayers. International Journal of Plasticity 103, 23-38. [15] Li, G., Wang, Y., Xiang, M., Liao, Y., Wang, K., Chen, J., 2018. Shock response of nanoporous magnesium by molecular dynamics simulations. International Journal of Mechanical Sciences 141, 143-156. [16] Liao, Y., Xiang, M., Li, G., Wang, K., Zhang, X., Chen, J., 2018. Molecular dynamics studies on energy dissipation and void collapse in graded nanoporous nickel under shock compression. Mechanics of Materials 126, 13-25. [17]. Wang, K., Chen, J., Zhang, X., Zhu, W., 2017. Interactions between coherent twin boundaries and phase transition of iron under dynamic loading and unloading. Journal of Applied Physics 122, 105107. [18]. Wang, K., Chen, J., Zhu, W., Hu, W., Xiang, M., 2017. Phase transition of iron-based single crystals under ramp compressions with extreme strain rates. International Journal of Plasticity 96, 56-80. [19]. Xiang, M., Cui, J., Yang, Y., Liao, Y., Wang, K., Chen, Y., Chen, J., 2017. Shock responses of nanoporous aluminum by molecular dynamics simulations. International Journal of Plasticity 97, 24-45. [20]. Wang, K., Zhu, W., Xiao, S., Chen, J., Hu, W., 2016. A new embedded-atom method approach based on the p th moment approximation. Journal of Physics: Condensed Matter 28, 505201. [21]. Wu, L., Wang, K., Xiao, S., Deng, H., Zhu, W., Hu, W., 2016. Atomistic studies of shock-induced phase transformations in single crystal iron with cylindrical nanopores. Computational Materials Science 122, 1-10. [22]. Wang, K., Zhu, W., Xiao, S., Chen, K., Deng, H., Hu, W., 2015. Coupling between plasticity and phase transition of polycrystalline iron under shock compressions. International Journal of Plasticity 71, 218-236. [23]. Wang, K., Xiao, S., Deng, H., Zhu, W., Hu, W., 2014. An Atomic Study on The Shock-Induced Plasticity and Phase Transition for Iron-based Single Crystals. International Journal of Plasticity 59, 180-198. [24]. Wang, K., Xiao, S., Liu, M., Deng, H., Zhu, W., Hu, W., 2013. Shock Waves Propagation and Phase Transition in Single Crystal Iron under Ramp Compression: Large Scale Parallel NEMD Simulations. Procedia Engineering 61, 122-129.