王宇杰 教授
研究机构: 交叉科学研究所
研究领域: 颗粒物质物理,软物质物理, 同步辐射X射线影像
办公地点: 理科楼5号楼827室
办公电话: 86-21-54743162
电子邮箱: yujiewang@sjtu.edu.cn
研究方向: 本研究组的主要研究兴趣是基于X射线成像技术为主要实验手段的实验软凝聚态物理和同步辐射应用。几个主要的研究内容包括颗粒物质非平衡态统计物理框架,微观尺度的结构和动力学过程以及如何建立宏微观联系的颗粒连续介质本构理论的微观基础。同时将X射线成像技术应用于流体,材料及生物医学影像。
个人主页: http://xray.sjtu.edu.cn/

简历:

1995年清华大学物理系获学士学位。2001年在麻省理工学院师从Prof. Birgeneau 获得物理学博士学位,研究方向是同步辐射X射线散射研究低维量子磁学系统。博士毕业后在美国阿贡国家实验室从事博士后和助理研究员研究,研究方向是同步辐射X射线成像学,发展了第一套同步辐射超快X射线成像系统。2009年9月被上海交通大学物理系聘为研究员。 2018年为上海交通大学长聘教授,2019年至今为上海交通大学特聘教授。近年来主要从事软物质物理和同步辐射成像学研究。入选教育部长江学者特聘教授(2021),百千万人才工程国家级人选并获“有突出贡献中青年专家”称号(2019),国务院政府特殊津贴(2020),上海市优秀学术带头人(2019),上海市浦江人才计划(2010)和教育部新世纪人才(2010)等人才计划。担任国际颗粒物质专业期刊《Granular Matter》编委和中国物理协会非晶态物理专业委员会委员。获上海交通大学优秀博士导师和上海交通大学科研成果二等奖。指导博士生获上海交通大学“学术之星”和上海交通大学“年度人物”称号。

主要著作:

  1. Structural Critical Scattering study of Mg-Doped CuGeO3, Y.J.Wang, V.Kiryukhin, R.J.Birgeneau, T.Masuda, I.Tsukada and K. Uchinokura, Phys. Rev. Lett. 83, 1676 (1999).
  2. Hard X-ray Quantitative Phase Contrast Imaging of Air Assisted Water Spray, Y.J. Wang, K. Fezzaa, J. Wang, K-S Im, W.K. Lee, K. Fezzaa, W.K. Lee, and J. Wang, Appl. Phys. Lett. 89, 151913 (2006).
  3. A Sagittally Focusing Double-Multilayer Monochromator for Ultrafast X-ray Imaging Applications, Y.J. Wang, S. Narayanan, D.M. Shu, A. Mashayekhi, J. Qian, J.Y. Liu, and J. Wang, Journal of Synchrotron Radiation 14, 138 (2007).
  4. Ultrafast Synchrotron X-ray Imaging of High-Speed Liquid Jet Breakup, Y.J. Wang, X. Liu, K.-S. Im, W.-K. Lee, J. Wang, F. Kamel, L.S. Hung, J.R. Winkelman, Nature Physics 4, 306 (2008).
  5. Similarity between primary and secondary liquid jet breakup mechanism, Y.J. Wang, K.-S. Im, K. Fezzaa, Phys. Rev. Lett 100, 154502 (2008).
  6. Ultrafast X-ray Phase-Contrast Imaging of the Droplets Coalescence Process, K. Fezzaa, Y.J. Wang,Phys. Rev. Lett 100, 104501 (2008).
  7. X-ray grating interferometer for biological imaging applications at Shanghai Synchrotron Radiation Facility, Y. Xi, B.Q. Kou, S.H. Sun, J.C. Qi, J.Q. Sun, J. Mohr, M. Borner, J. Zhao, L.X. Xu, T.Q. Xiao, Y.J. Wang, Journal of Synchrotron Radiation 19, 821 (2012).
  8. Similarity of wet granular packings to gels,  J.D. Li, Y.X. Cao, C.J. Xia, B.Q. Kou, X.H. Xiao, K. Fezzaa, Y.J. Wang, Nature Communications 5, 5014 (2014).
  9. The structural origin of the hard-sphere glass transition in granular packing, C.J. Xia, J.D. Li, Y.X. Cao, B.Q. Kou, X.H. Xiao, K. Fezzaa, T.Q. Xiao, Y.J. Wang, Nature Communications 6, 8409 (2015). 
  10. Granular packing as model glass formers (review article), Y.J. Wang, Chinese Physics B 26, 1 (2017).
  11. Origin of noncubic scaling law in disordered granular packing, C.J. Xia, J.D. Li, B.Q. Kou, Y.X. Cao, Z.F. Li, X.H. Xiao, Y.N. Fu, T.Q. Xiao, L. Hong, J. Zhang, W. Kob, Y.J. Wang, Phys. Rev. Lett. 118, 238002 (2017).
  12. Dynamical transition of collective motions in dry proteins, Z. Liu, J. Huang, M. Tyagi, H. O'Neill, Q. Zhang, E. Mamontov, N. Jain, Y.J. Wang, J. Zhang, J.C. Smith, L. Hong, Phys. Rev. Lett. 119, 048101 (2017).
  13. Experimental studies of vibrational modes in a two-dimensional amorphous solid, L. Zhang, J. Zheng, Y.Q. Wang, L. Zhang, Z.H. Jin, L. Hong, Y.J. Wang, J. Zhang, Nature Communications 8, 67 (2017).
  14. Granular materials flow like complex fluids, B.Q. Kou, Y.X. Cao, J.D. Li, C.J. Xia, Z.F. Li, H.P. Dong, A. Zhang, J. Zhang, W. Kob, Y.J. Wang, Nature 551, 360 (2017).
  15. Translational and rotational dynamical heterogeneities in granular systems, B.Q. Kou, Y.X. Cao, J.D. Li, C.J. Xia, Z.F. Li, H.P. Dong, A. Zhang, J. ZHang, W. Kob, Y.J. Wang, Phys. Rev. Lett 121, 018002 (2018).
  16. Structural and topological nature of plasticity in sheared granular materials, Y.X. Cao, J.D. Li, B.Q. Kou, C.J. Xia, Z.F. Li, R.C. Chen, H.L. Xie, T.Q. Xiao, W. Kob, L. Hong, J. Zhang, Y.J. Wang, Nature Communications 9, 2911 (2018).
  17. Energy fluctuations in slowly sheared granular materials, J. Zheng, A.L. Sun, Y.J. Wang, J.Zhang, Phys. Rev. Lett 121, 248001 (2018).
  18. Connecting shear localization with the long-range correlated polarized stress fields in granular materials, Y.Q. Wang, Y.J. Wang, J. Zhang, Nature Communications 11,4349 (2020).
  19. Friction-Controlled Entropy-Stability Competition in Granular Systems, X.L. Sun, W. Kob, R. Blumenfeld, H. Tong , Y.J. Wang, J. Zhang, Phys. Rev. Lett. 125, 268005 (2020).
  20. X-ray tomography investigation of cyclically sheared granular materials, Y. Xing, J. Zheng, J.D. Li, Y.X. Cao, W. Pan, J. Zhang, Y.J. Wang, Phys. Rev. Lett. 126, 048002 (2021).
  21. Microscopic structure and dynamics study of granular segregation mechanism by cyclic shear, Z.F. Li, Z.K. Zeng, Y. Xing, J.D. Li, J. Zheng, Q.H. Mao, J. Zhang, M.Y. Hou, Y.J. Wang, Science Advances, 7, eabe8737 (2021).
  22. Experimental Test on Edwards Volume Ensemble of Tapped Granular Packings,Ye Yuan, Yi Xing, Jie Zheng, Zhifeng Li, Houfei Yuan, Shuyang Zhang, Zhikun Zeng, Chengjie Xia, Hua Tong, Walter Kob, Jie Zhang, Yujie Wang,Phys. Rev. Lett. 127 018002 (2021) (Editors’ Suggestion, Featured in Physics).
  23. Connecting Packing Efficiency of Binary Hard Sphere Systems to Their Intermediate Range Structure, Houfei Yuan, Zhen Zhang, Walter Kob and Yujie Wang, Phys. Rev. Lett. , 107, 278001(2021).