理论软物质交叉研究中心
发布时间:2022-06-10 09:49:00

教师团队:汪志勇,张博凯


在读学生:盛康,文佳,彭洁,李靖,李洪尧


研究方向:软物质表界面物理,胶体聚合物玻璃化转变,纳米离子通道,能量转换与储存低维软材料计算设计,活性物质流体力学及非平衡统计


招生愿景:对富有创造力且自律的学生,课题组将给予充分的自主权利并不遗余力地予以配合;但如果未来的你跟导师一样资质平平,必须打碎夕阳,揉进月光,褪去迷茫,背上行囊,只为不负诗中的远方。桃李不言,下自成蹊,课题组热忱欢迎志同道合的年轻伙伴加盟。


主持的科研项目


自驱微生物-聚合物混合溶液中流体力学相互作用的数值与理论研究

国家自然科学基金 11904320, 2020.01-2022.12


离子液体界面绑定机制研究

西南大学人才引进基金 swu019021, 2019.07-2022.06


高脆性聚合物玻璃的微观理论研究

国家自然科学基金 11847115, 2019.01-2019.12


生命体系中极性逆转与同性相吸的物理机制研究

国家自然科学基金 11774041, 2018.01-2021.12


受限条件下的离子行为与嵌段共聚物共混自组装

重庆市基础科学与前沿技术研究专项重点基金 cstc2015jcyjBX0056, 2015.12-2018.12


生物界面电荷反转的计算机模拟研究

重庆市自然科学基金 cstc2012jjA00019, 2012.09-2015.08


基于分子模拟的双电层极性逆转与过度充电的物理驱动机制研究

国家自然科学基金 11104364, 2012.01-2014.12


代表性学术论文


[1] K. Sheng, B. Zhang, H.-K. Yuan, and Z.-Y. Wang

Strain-engineered topological phase transitions in ferrovalley 2H-RuCl2 monolayer

Physical Review B, 105, 195312 (2022)

[2] K. Sheng, Q. Chen, H.-K. Yuan, and Z.-Y. Wang

Monolayer CeI2: An intrinsic room-temperature ferrovalley semiconductor

Physical Review B, 105, 075304 (2022)

[3] K. Sheng, H.-K. Yuan, and Z.-Y. Wang

Monolayers gadolinium halides GdX2 (X = F, Cl, Br): intrinsic ferrovalley materials with spontaneous spin and valley polarizations

Physical Chemistry Chemical Physics, 24, 3865-3874 (2022)

[4] K. Sheng, H.-K. Yuan, and Z.-Y. Wang

Intrinsic ferromagnetism in 2D h-CrC semiconductors with strong magnetic anisotropy and high Curie temperatures

Journal of Materials Chemistry C (Hot Paper by Editors’ Choice), 9, 16495-16505 (2021)

[5] B. Zhang, P. Leishangthem, Y. Ding, and X. Xu

An effective and efficient model of the near field hydrodynamic interactions for active suspensions of bacteria

Proceedings of the National Academy of Sciences, 118, e2100145118 (2021)

[6] B. Zhang, J. Li, J. Hua, and L. Liu

Theory of polymer diffusion in polymer–nanoparticle mixtures: effect of nanoparticle concentration and polymer length

Soft Matter, 17, 4632-4642 (2021)

[7] Z.-Y. Wang, T. Yang, and X. Wang

Structural analysis of confined monovalent salts: Combined effects of steric hindrance, surface charge representation, and dielectric response

Electrochimica Acta, 336, 135707 (2020)

[8] Q. Duan, J. Ji, X. Hong, Y. Fu, C. Wang, K. Zhou, X. Liu, H. Yang, and Z.-Y. Wang

Design of hole-transport-material free CH3NH3PbI3/CsSnI3 all-perovskite heterojunction efficient solar cells by device simulation

Solar Energy (ESI Highly Cited Paper As of Mar 2021-Feb 2022), 120, 213-218 (2020)

[9] J. Li and B. Zhang

Effect of chain length on structure and dynamics in a melt of semiflexible rings

Europhysics Letters, 130, 56001 (2020)

[10] K. Sheng, Z.-Y. Wang, H.-K. Yuan, and H. Chen

Two-dimensional hexagonal manganese carbide monolayer with intrinsic ferromagnetism and half-metallicity

New Journal of Physics, 22, 103049 (2020)

[11] T. Liao, H. Zhang, and Z.-Y. Wang

Improved Design of a Thermophotovoltaic Device

IEEE Transactions on Electron Devices, 62, 4709-4712 (2020)

[12] Z.-Y. Wang, P. Zhang, and Z. Ma

On the physics of both surface overcharging and charge reversal at heterophase interfaces

Physical Chemistry Chemical Physics, 20, 4118-4128 (2018)

[13]Z.-Y. Wang and J. Wu

Ion association at discretely-charged dielectric interfaces: Giant charge inversion

Journal of Chemical Physics (Featured Article: AIP News), 147, 024703 (2017)

[14] Z.-Y. Wang and Z. Ma

Examining the Contributions of Image-Charge Forces to Charge Reversal: Discrete Versus Continuum Modeling of Surface Charges

Journal of Chemical Theory and Computation, 12, 2880-2888 (2016)

[15]Z.-Y. Wang

Charge reversal at a planar boundary between two dielectrics

Physical Review E (Highlights in Kaleidoscope), 93, 012605 (2016)

[16] Z.-Y. Wang

Image-induced overcharging in the weakly charged surfaces

Journal of Statistical Mechanics: Theory and Experiment, (2016), 043205

[17] B. Zhang, H.-s. Li, J. Li, K. Chen, W.-d. Tian, and Y. –q. Ma

Unique role of bond length in the glassy dynamics of colloidal polymers

Soft Matter, 12, 8104-8111 (2016)

[18] J. Li, B. Zhang, H.-s. Li, K. Chen, and W.-d. Tian, and P.-q. Tong

Glassy dynamics of model colloidal polymers: The effect of “monomer” size

Journal of Chemical Physics, 144, 204509 (2016)

[19] Z.-Y. Wang, Z. Ma, and Y.-q. Ma

Suppression and promotion of charge inversion in the presence of multivalent coions

Physical Review E (Rapid Communication), 92, 060303(R) (2015)

[20] H.-s. Li, B. Zhang, J. Li, W.-d. Tian, and K. Chen

Brush in the bath of active particles: anomalous stretching of chains and distribution of particles

Journal of Chemical Physics, 143, 224903 (2015)

[21] Q. Liang, Q.-Y. Wu, and Z.-Y. Wang

Effect of hydrophobic mismatch on domain formation and peptide sorting in the multicomponent lipid bilayers in the presence of immobilized peptides

Journal of Chemical Physics (Image for Outside Front Cover), 141, 074702 (2014)

[22] B. Zhang, H.-s. Li, W.-d. Tian, K. Chen, and Y.-q. Ma

Theory of activated dynamics and glass transition of hard colloids in two dimensions

Journal of Chemical Physics, 140, 094506 (2014)

[23] Y.-P. Xie, Z.-Y. Wang, and Z. F. Hou

The phase stability and elastic properties of MgZn2 and Mg4Zn7 in Mg-Zn alloys

Scripta Materialia, 68, 495-498 (2013)

[24] Z.-Y. Wang and Y.-q. Ma

Computational evidence of two driving mechanisms for overcharging in an electric double layer near the point of zero charge

Physical Review E (Brief Report), 85, 062501 (2012)

[25] X.-W. Wang, D.-Y. Zhang, S.-Q. Tang, L.-J. Xie, Z.-Y. Wang, and L.-M. Kuang

Photonic two-qubit parity gate with tiny cross-Kerr nonlinearity

Physical Review A, 85, 052326 (2012)

[26] Z.-Y. Wang, Y.-P. Xie, Q. Liang, Z. Ma, and J. Wei

Looking deeper into the structure of mixed electric double layers near the point of zero charge

Journal of Chemical Physics, 137, 174707; 249902(E) (2012)

[27] Z.-Y. Wang and Y.-q. Ma

A molecular simulation study on the role of ionic size and dielectric images in near-surface ion distribution far from the strong-coupling limit

Journal of Chemical Physics, 136, 234701 (2012)

[28] Z.-Y. Wang and Y.-q. Ma

Impact of Headgroup Charges, Ionic Sizes, and Dielectric Images on Charge Inversion: A Monte Carlo Simulation Study

Journal of Physical Chemistry B, 114, 13386-13392 (2010)

[29] Z.-Y. Wang and Y.-q. Ma

Insights from Monte Carlo simulations on charge inversion of planar electric double layers in mixtures of asymmetric electrolytes

Journal of Chemical Physics, 133, 064704 (2010)

[30] Z.-Y. Wang and Y.-q. Ma

Monte Carlo determination of mixed electrolytes next to a planar dielectric interface with different surface charge distributions

Journal of Chemical Physics, 131, 244715 (2009)


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