— 2023-至今:长聘教轨副教授,beat365中文版官方网站beat365中文版官方网站
— 2017-2022:博士后,康斯坦茨大学(University of Konstanz)物理系(德国)
— 2014-2017:博士,香港科技大学物理系
— 2012-2014:硕士,香港科技大学物理系
— 2008-2012:学士,北京大学物理学院
[9] Xin Cao, Debankur Das, Niklas Windbacher, Felix Ginot, Matthias Krüger, Clemens Bechinger. Memory Induced Magnus Effect. Nature Physics 19, 1904-1909 (2023)
[8] Panizon, E., Silva, A., Cao, X., Wang, j., Bechinger, C., Vanossi, A., Tosatti, E., Manini, N. Frictionless nanohighways on crystalline surfaces. Nanoscale, 15, 1299 (2023).
[7] Cao, X., Silva, A., Panizon, E., Vanossi A., Manini, N., Tosatti, E., Bechinger C. Moire-pattern evolution couples rotational and translational friction at crystalline interfaces. Phys. Rev. X, 12, 012059 (2022).
[6] Cao, X., Panizon, E.,Vanossi A., Manini, N., Tosatti, E., Bechinger C. Pervasive orientational and directional locking at geometrically heterogeneous sliding interfaces. Phys. Rev. E 103, 012606 (2021).
[5] Cao, X., Panizon, E., Vanossi, A., Manini, N., Tosatti, E., Bechinger, C. Pile-up transmission and reflection of topological defects at grain boundaries in colloidal crystals. Nat. Commun, 11, 3079 (2020).
[4] Cao, X., Panizon, E., Vanossi, A., Manini, N., Bechinger, C. Orientational and directional locking of colloidal clusters driven across periodic surfaces. Nat. Phys. 15, 776–780 (2019).
[3] Cao, X., Zhang, H. & Han, Y. Release of free-volume bubbles by cooperative-rearrangementregions during the deposition growth of a colloidal glass. Nat. Commun. 8, 362 (2017).
[2] Su, Y., Lai, P. Y., Ackerson, P. J., Cao, X., Han, Y. & Tong, P. Colloidal diffusion over aquasicrystalline-patterned surface.J. Chem. Phys. 146, 214903 (2017).
[1] Cao, X., Wang, F. & Han, Y. Ground-state phase-space structures of two-dimensional +-Jspin glasses: A network approach.Phys. Rev. E 91, 062135 (2015).
— 2021:国家自然科学基金优秀青年科学基金项目(海外)
— 2018-2020:德国洪堡博士后奖学金(Humboldt Fellowship)
欢迎对软物质和胶体物理感兴趣的同学加入我们课题组。我们也长期招聘具有胶体物理实验经验的博士后青年学者,提供有竞争力的薪资待遇和实验条件。另外,我们也欢迎对胶体物理感兴趣的本科生加入课题组参与实验工作和研究。有意者发送申请至xin.cao@sjtu.edu.cn
加入课题组后将掌握的知识与技能:
软凝聚态物理与胶体物理领域的基础知识与前沿研究状况
光刻技术,微米级胶体颗粒物溶液的制备技术,简单的激光光路搭建技术,利用激光、磁场等外场操控颗粒物的运动
显微镜成像和图像处理技术,包括同时对大量(1~100000)微米级颗粒物进行识别和轨迹追踪(matlap)
数据处理与分析能力,运用统计物理和其它软凝聚态物理相关的理论知识对新发现的颗粒物运动现象进行理论解释
利用以上知识和技术,独立开展科研、探索未知的能力
