姓 名:张宇航
性 别:男
出生年月:1997年8月
职 称:讲师
学 历:博士研究生
学 位:工学博士
邮 箱:zhangyuhangwhut@whut.edu.cn
个人简介
研究先进结构与材料的多尺度力学行为,聚焦从微观机理到宏观性能的跨尺度力学行为调控,包括:(1)微纳米力学。揭示新型纳米结构材料(纳米多孔金属、纳米复合材料、二维纳米材料)的变形-失效机制、界面力学效应等基础科学问题,建立考虑尺寸效应与表面效应的微纳米力学理论框架;(2)宏微观机械超材料。开发具有非经典变形模式与能量吸收路径的超材料,提出力学性能调控机理,推动工程应用;(3)微纳米制造。揭示微纳制造(纳米压印、纳米切削、激光冲击、微尺度焊接)中的力学机理,建立"力学机理-工艺优化-性能实现"的制造方法论。发表SCI论文50余篇,其中以第一作者身份在Materials & Design、International Journal of Mechanical Sciences、Science China-Technological Sciences、Mechanics of Materials、Physical Chemistry Chemical Physics、Journal of the Mechanical Behavior of Biomedical Materials、Journal of Applied Physics、Journal of Non-Crystalline Solids等期刊发表论文20余篇,受邀担任Nature Communications、Scripta Materialia、International Journal of Solids and Structures等期刊审稿人。
教育和工作经历
2024.07–至今 武汉理工大学,机电工程学院,讲师
2021.09–2024.06 武汉大学,机械设计及理论,博士
2019.09–2021.06 武汉大学,机械工程,硕士
2015.09–2019.06 浙江工业大学,机械工程,学士
主要研究方向
(1)微纳米材料的力学行为
(2)机械超材料设计与力学性能调控
(3)微纳制造中的力学问题
科研项目
(1)湖北省自然科学基金青年B类项目,2025.03—2027.02,10万,项目负责人
代表性论文
[1] Zhang Y. H., Xu J. F., Hu Y. Q., Ding S. H., Wu W. W., Xia R. Nanoindentation and nanotribology behaviors of open-cell metallic glass nanofoams. International Journal of Mechanical Sciences, 2023, 249: 108254.
[2] Zhang Y. H., Hu Y. Q., Xu J. F., Ding S. H., Wu W. W., Xia R. Ligament rotation-dominated creep in stochastic bicontinuous nanoporous metallic glass. Materials & Design, 2023, 236: 112480.
[3] Zhang Y. H., Xu J. F., Hu Y. Q., Su L., Ding S. H., Wu W. W., Xia R. Fracture toughness and destructive mechanism of ductile nanoporous metallic glass and its crystal-impregnated nanocomposite. Science China-Technological Sciences, 2023, 66(11): 3328-3342.
[4] Zhang Y. H., Xu J. F., Hu Y. Q., Ding S. H., Wu W. W., Xia R. Dynamic characterization of shock wave responses of bicontinuous nanoporous amorphous alloys: Microstructure effects. Mechanics of Materials, 2022, 173: 104410.
[5] Zhang Y. H., Su L., Xu J. F., Hu Y. Q., Liu X. M., Ding S. H., Li J. J., Xia R. Molecular dynamics simulations of cold welding of nanoporous amorphous alloys: effects of welding conditions and microstructures. Physical Chemistry Chemical Physics, 2022, 24(41): 25462-25479.
[6] Zhang Y. H., Xu D. F., Li J. J., Zhang Z. N., Ding S. H., Wu W. W., Xia R. Mechanical properties and clamping behaviors of snow crab claw. Journal of the Mechanical Behavior of Biomedical Materials, 2021, 124: 104818.
[7] Zhang Y. H., Xian Y. H., Li J. J., Ding S. H., Liu S., Xia R. Atomistic investigation on the mechanical properties of 3D nanoporous metallic glasses under uniaxial tension and compression. Materials Today Communications, 2021, 27: 102460.
[8] Zhang Y. H., Xu J. F., Hu Y. Q., Ding S. H., Xia R. Cold welding of ultrathin metallic glass nanowires with side-to-side contact using molecular dynamics simulations. Materials Today Communications, 2022, 32: 103937.
[9] Zhang Y. H., Zhou H. J., Liu X. M. Mechanical Properties of CuZr Amorphous Metallic Nanofoam at Various Temperatures Investigated by Molecular Dynamics Simulation. Materials, 2025, 18(14): 3423.
[10] Zhang Y. H., Yuan L., Hu Y., Xia R. Size effect and its atomistic origin on the mechanical properties of open-cell nanoporous amorphous alloy. Journal of Non-Crystalline Solids, 2025, 647: 123275.
[11] Zhang Y. H., Liu X., Hu Y., Ding S., Xia R. Mechanical responses and deformation mechanisms of nanoporous glassy alloy under multiaxial loading: a molecular dynamics study. Journal of Materials Science, 2025: 15906–15920.
[12] Zhang Y. H., Li J. J., Hu Y. Q., Ding S. H., Du F. Y., Xia R. Mechanical properties and scaling laws of polycrystalline CuZr shape memory alloy. Journal of Applied Physics, 2021, 130(15): 155106.
[13] Zhang Y. H., Li J. J., Zhou H. J., Hu Y. Q., Ding S. H., Xia R. Cold welding behavior of metallic glass nanowires: Insights from large-scale numerical simulations. Journal of Materials Science, 2021, 56(28): 15906-15920.
[14] Zhang Y. H., Zhou H. J., Ding S. H., Hu Y. Q. Atomistic insights into the mechanical behaviors of nanocrystalline FeNiCrCoCu high entropy alloy under tension and compression. Physica Scripta, 2025, 100(3): 035407.
[15] Zhang Y. H., An Q., Li J. J., Lu B. B., Wu W. W., Xia R. Strengthening mechanisms of graphene in copper matrix nanocomposites: A molecular dynamics study. Journal of Molecular Modeling, 2020, 26(12): 335.
[16] Zhang Y. H., Ding S. H., Zhou H. J. Atomistic Study on the Mechanical Behaviors of Nanoporous Glassy Alloys under Shear Loading: Effects of Porosity and Specific Surface Area. Physica Status Solidi a-Applications and Materials Science, 2025, 222(8): 2400813.
[17] Zhang Y. H., Xu J. F., Hu Y. Q., Li J. J., Ding S. H., Xia R. Nanoindentation characteristics of nanocrystalline B2 CuZr shape memory alloy via large-scale atomistic simulation. Journal of Molecular Modeling, 2022, 28(10): 317.
[18] Zhang Y. H., Zhou H. J., Hu Y. Q. Mechanical response and its dependence on microstructures for nanoporous gold under shear loading. Materials Today Communications, 2025, 42: 111255.
[19] Zhang Y. H., Li J., Zhang Q., Ding S., Wu W., Xia R. Tetrachiral nanostructured metallic glasses with mechanically tunable performance. Materials Chemistry and Physics, 2022, 276: 125315.
[20] Zhang Y. H., Li J. J., Hu Y. Q., Ding S. H., Wu W. W., Xia R. Fatigue responses of metallic glass-based stochastic network nanomaterial: Superior strain-hardening ability. Fatigue & Fracture of Engineering Materials & Structures, 2024, 47(4): 1208-1218.
[21] Zhang Y. H., Li J., Hu Y., Ding S., Du F., Xia R. Characterization of the deformation behaviors under uniaxial stress for bicontinuous nanoporous amorphous alloys. Physical Chemistry Chemical Physics, 2022, 24(2): 1099-1112.
[22] Zhang Y. H., Xu J. F., Hu Y. Q., Li J. J., Ding S. H., Xia R. Dynamic mechanical behaviors of metallic glass-shape memory alloy bilayered nanocomposite under shock wave compression. Journal of Non-Crystalline Solids, 2022, 581: 121419.