王煜，男，博士，副教授，硕士生导师。

主要研究方向：智能材料多场耦合力学；主要研究方法：多物理场有限元计算、智能材料微结构相场模拟；

相关研究成果已应用于信息（例如量子器件、超级计算机）、航空航天、能源、医疗等领域。

近五年内，在Science Bulletin, Acta Materialia(3篇), Int. J. Mech. Sci.(3篇), Int. J. Solids Struct., Phys. Rev. Lett., Phys. Rev. B(2篇), Phys. Rev. Applied(2篇), ACS Nano(2篇)，固体力学学报等期刊上发表高水平论文20余篇。

主持国家自然科学基金委员会青年项目、参与国家自然科学基金委员会面上项目、日本学术振兴会科研费项目研究多项；获国家留学基金委（CSC）公派留学奖学金、京都大学全额奖学金、浙江大学优秀研究生、应怀樵奖学金、湖南大学一等奖学金等奖项；担任Elsevier系列（如Acta Materialia）和Physical Review系列国际期刊的审稿人；受邀参加全国固体力学学术会议、JSMAMS、美国MRS Fall、日本WCCM-APCOM、ICMR、PF24等重要学术会议，多次作分组报告和主题报告（keynote）。

在海外工作期间，协助培养本科生2名、硕士生3名、博士生1名。

个人学术主页：

https://orcid.org/0000-0002-2947-7262

近期研究兴趣：

固体力学、智能材料、凝聚态物理、智能建造

1）自旋电子学与量子器件

2）拓扑微结构应变工程

3）智能材料多场耦合断裂力学

课题组经费充足，学风自由，欢迎力学、物理、材料、机械、土木或交叉学科背景的研究生加入！

主要纵向科研项目

[1] 国家自然科学基金青年科学基金项目，12402194，"考虑温度效应的铁磁材料磁化动力学特性的应变调控研究"，2025/01-2027/12，30万元，在研，主持

[2] 国家自然科学基金面上项目，11972320，"铁磁材料中拓扑磁结构的力学调控"，2020/01-2023/12，62万元，已结题，参与

近五年已发表论文（第一作者#，通讯作者*）：

[1] Y. Wang#*, R. Manabe, et al. Stability and deformation of a vacancy defect in skyrmion crystal under external magnetic and temperature fields. Acta Materialia. 120381 (2024) 一区/Q1/TOP, IF = 9.209

[2] Y. Wang#*, J. Wang, et al. Dynamic Precursor Effect: the magnitude-fluctuated coherent spin waves emitted by skyrmions. Acta Materialia. 250, 118867 (2023) 一区/Q1/TOP, IF = 9.209

[3] Y. Wang#*, T. Shimada, et al. The rectilinear motion of the individual asymmetrical skyrmion driven by temperature gradients. Acta Materialia. 221, 117383 (2021) 一区/Q1/TOP, IF = 9.209

[4] Y. Wang#*, J. Wang, et al. Mechanical effects on skyrmion-skyrmion interaction. Int. J. Mech. Sci. 108699 (2023) 一区/Q1/TOP, IF = 7.3

[5] I. A. Malik#, H. Huang#, Y. Wang#, et al. Inhomogeneous-strain-induced magnetic vortex cluster in one-dimensional manganite nanowire. Science Bulletin. 65, 201-207 (2020) 一区/Q1/TOP, IF = 20.577

[6] T. Xu, Y. Ichiki, K. Masuda, Y. Wang, et al. Ultrasmall polar skyrmions and merons in SrTiO3 heterostructures by polaron engineering. ACS Nano. 17(11), 10836 (2023) 一区/Q1/TOP/自然指数期刊, IF = 18.027

[7] K. Kasai, T. Nojima, Y. Wang. et al. Mechanical Writing of Polar Skyrmionic Topological States via Extrinsic Dzyaloshinskii–Moriya-like Flexoelectricity in Ferroelectric Thin Films. ACS Nano. (2024) 一区/Q1/TOP/自然指数期刊, IF = 18.027

[8] S. Wu, Y. Zhang, C. Tian, J. Zhang, M. Wu, Y. Wang et al. Prototype Design of a Domain-Wall-Based Magnetic Memory Using a Single Layer La0.67Sr0.33MnO3 Thin Film. ACS Appl. Mater. Interfaces. 13, 23945-23950 (2021) 二区/Q1/TOP, IF = 10.383

[9] T. Xu, C. Wang, Y. Zhu, Y. Wang, et al. Efficient phase-field simulation for linear superelastic NiTi alloys under temperature gradients. Int. J. Mech. Sci. 259, 108592 (2023) 一区/Q1/TOP, IF = 7.3

[10] J. Sun, S. Shi, P. Han, Y. Wang. et al. Strain mediated transition between skyrmion and antiskyrmion in ferromagnetic thin films. Int. J. Mech. Sci. (2024) 一区/Q1/TOP, IF = 7.3

[11] Y. Wang#, J. Sun, T. Shimada, et al. Ferroelectric control of magnetic skyrmions in multiferroic heterostructures. Physical Review B. 102, 014440 (2020) 二区/Q2/TOP/自然指数期刊, IF = 4.036

[12] Y. Wang#*, J. Wang, et al. Effective modeling of magnitude-fluctuated magnetization dynamics: Dynamic precursor effect in magnets. Physical Review B. 106, 094423 (2022) 二区/Q2/TOP/自然指数期刊, IF = 4.036

[13] Y. Wang#*, T. Kitamura, et al. Mechanical acceleration and control on thermal motion of magnetic skyrmion. Physical Review Applied. 18, 014049 (2022) 二区/Q1, IF = 4.931

[14] Y. Wang#*, J. Wang, et al. Exponential temperature effects on skyrmion-skyrmion interaction. Physical Review Applied. 18, 044024 (2022) 二区/Q1, IF = 4.931

[15] Y. Wang#, C. Liu, H. Yu and J. Wang. Phase field simulations on domain switching-induced toughening or weakening in multiferroic composites. Int. J. Solids Struct. 178-179, 48-58. (2019) 二区/Q1, IF = 3.9

[16] Y. Wang# and J. Wang. The temperature–strain phase diagrams of ferromagnetic thin films under different magnetic fields. J. Phys.: Condens. Matter. 33, 235802 (2021) (邀稿) 三区/Q3, IF = 2.745

[17] T. Shimada#, Y. Wang#, et al. Emergence of non-trivial polar topologies hidden in singular stress field in SrTiO3: Topological strain-field engineering. J. Phys.: Condens. Matter. 33, 505301 (2021) 三区/Q3, IF = 2.745

[18] Y. Wang#, Y. Shi, and J. Wang. Mechanical control of topological magnetic structures in multiferroic composites. 固体力学学报. 41(2), 142-150 (2020) (邀稿)

[19] J. Sun, S. Shi, Y. Wang. et al. Phase Field Modeling of Topological Magnetic Structures in Ferromagnetic Materials Domain Wall, Vortex and Skyrmion. Acta Mechanica. (2023) (邀稿综述) 三区/Q2, IF = 2.645

[20] K. Kasai, T. Hamaguchi, Y. Wang. et al. Singular stress field induced two-dimensional topological polar structures in SrTiO3: Topological number manipulation via loading modes. Computational Materials Science (2024).

[21] T. Xu, C. Wu, S. Zheng, Y. Wang. et al. Mechanical Rippling for Diverse Ferroelectric Topologies in Otherwise Nonferroelectric SrTiO3 Nanofilms. Physical Review Letters (2024) 一区/Q1/TOP/自然指数期刊

[22] Y. Wang#*, J. Wang*. Dynamic precursor effect: The influence of temperature on dynamic skyrmion-skyrmion interaction. Acta Mechanica. (2024) (邀稿) 三区/Q2, IF = 2.645