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2006——2010年:湖南大学 应用物理学专业 理学学士

2010——2015年:湖南大学 材料科学与工程学院 工学博士


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——2020.06:北京应用物理与计算数学研究所 工作,先后为助理研究员(2018.062019.11)和副研究员(自2019.12起)

2020.07——至今:湖南大学 材料科学与工程学院 副教授




[1] 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.

[2] 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.

[3] 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.

[4] 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.

[5] 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.

[6] 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.

[7] 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.

[8] 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.

[9] 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.

[10]. 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.

[11]. 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.

[12]. 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.

[13]. 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.

[14]. 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.

[15]. 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.

[16]. 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.

[17]. 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.