崔冰宇

助理教授

教育背景

博士(剑桥大学)

硕士(剑桥大学)

学士(帝国理工学院)

研究领域
软物质;统计物理;化学物理;量子物理基础
学术领域
物理,数学与应用数学,化学,材料学
个人网站
电子邮件
bycui@cuhk.edu.cn
个人简介

崔冰宇博士于2015年在英国帝国理工学院取得数学与应用数学学士学位。2016年在英国剑桥大学取得应用数学与理论物理硕士学位。2016-2017年在日本东京大学物性研究所担任科研助理。2020年10月通过剑桥大学物理学博士研究生答辩后至2023年11月分别在以色列特拉维夫大学和美国宾夕法尼亚大学从事博士后研究。自2023年12月起,他加入香港中文大学(深圳)理工学院,担任助理教授。

他的研究兴趣包括但不限于非晶态物理,非平衡态统计物理,光与物质作用理论,激发态动力学,量子力学基础,量子测量理论等。他主要通过构建解析模型或者开发数值计算方法,从原子分子层面上理解或预测材料的物理化学性质。

学术著作

[20] B. Cui, The classical dynamics for the center of mass of a large quantum system, Physics Letters A, accepted, 482, 129041 (2023).

[19] B. Cui, M. Sukharev, A. Nitzan, Comparing semiclassical mean-field and 1-exciton approximations in evaluating optical response under strong light-matter coupling conditions, The Journal of Chemical Physics, accepted, 158, 164113 (2023).

[18] B. Cui, M. Sukharev, A. Nitzan, Short-time particle motion in one and two-dimensional lattice with site disorder, The Journal of Chemical Physics, 158, 164112 (2023).

[17] B. Cui, A. Nitzan, “Collective response in light-matter interactions: The interplay between electronic strong coupling and local dynamics”, The Journal of Chemical Physics 157, 114108, (2022) Editor’s pick, the 2022 JCP Editors’ Choice.

[16] T. Li, B. Cui, J. E. Subtonik, A. Nitzan, Molecular polaritonics: Chemical Dynamics under strong Light-Matter Coupling, Annual Review of Physical Chemistry 73, 1 (2022).

[15] B. Cui, G. T. Craven, A. Nitzan, Heat transport induced by electron transfer: A general temperature quantum calculation, The Journal of Chemical Physics 155, 194104 (2021).

[14] B. Cui, A. Zaccone, Vibrational density of states of amorphous solids with long-ranged power-law

correlated disorder in elasticity, The European Physical Journal E 43, 72 (2020).

[13] B. Cui, A. Zaccone, Analytical prediction of logarithmic Rayleigh scattering in amorphous solids from tensorial heterogeneous elasticity with power-law disorder, Soft Matter 16, 7797 (2020).

[12] B. Cui, E. Terentjev, Comparison of the Helmholtz, Gibbs and Collective-modes to obtain nonaffine elastic constants, Journal of the Mechanics and Physics of Solids 140, 103954 (2020).

[11] B. Cui, J. F. Gebbia, M. Romamini, S. Rudic, R. Fernandez-Perea, F. J. Bermejo, J.-L. Tamarit, A. Zaccone, Secondary relaxation in the terahertz range in 2-adamantanone from theory and experiments, Physical Review B 101, 104202 (2020).

[10] B. Cui, A. Zaccone, D. Rodney, Nonaffine lattice dynamics with the Ewald method reveals strongly nonaffine elasticity of α-quartz, The Journal of Chemical Physics, 151, 224509 (2019).

[9] M. Baggioli, B. Cui, A. Zaccone, Theory of phonon glass behaviour in host-guest crystalline solids with avoided crossing, Physical Review B 100, 220201 (2019).

[8] B. Cui, G. Ruocco, A. Zaccone, Theory of elastic constants of athermal amorphous solids with internal stresses, Granular Matter 21, 69 (2019).

[7] B. Cui, O. Sugino, Lattice mismatch pattern and the Dirac point of a monolayer borophene, Vacuum and Surface Science 61, 11 (2018).

[6] B. Cui, Z. Evenson, B. Fan, M Li, W.-H. Wang, A. Zaccone, Possible origin of β-relaxation in metallic glasses from atomic-mass differences of the constituents, Physical Review B 98, 144201 (2018).

[5] B. Cui, J. F. Gebbia, J.-L. Tamarit, A. Zaccone, Disentangling α and β relaxation in orientationally disordered crystals with theory and experiments, Physical Review E 97, 053001 (2018).

[4] B. Cui, A. Zaccone, Generalized Langevin Equation and non-Markovian fluctuation-dissipation theorem for particle-bath systems in external oscillating fields, Physical Review E 97, 060102 (2018).

[3] B. Cui, J. Yang, J. Qiao, L. Dai, M. Jiang, Y.-J. Wang, A. Zaccone, Atomic theory of viscoelastic response of metallic glasses, Physical Review B 96, 094203 (2017).

[2] B. Cui, R. Milkus, A. Zaccone, Direct link between soft vibrational modes and dielectric α-relaxation in glasses, Physical Review E 95, 022603 (2017).

[1] B. Cui, R. Milkus, A. Zaccone, The relation between stretched-exponential relaxation and the vibrational density of stated in glassy disordered systems, Physics Letters A 381, 446 (2017).