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1. J.H. Li, X.K. Ma*, K.J. Lu, Y.F. Wang*, Y.T. Zhu*. Unusual deformation mechanisms evoked by hetero-zone interaction in a heterostructured FCC high-entropy alloy. Acta Materialia 282 (2025) 120516. (建立了界面长程内应力模型，揭示了界面长程内应力的分布规律，并基于w_max Principle优化微结构设计以提高长程内引力，进而探讨了长程内应力效应：直接贡献强化、提高内应力以激活“硬”塑性机制)
2. Y.F. Wang, Y.G. Wei*. Strain energy density maximization principle for material design and the reflection in trans-scale continuum theory. Journal of the Mechanics and Physics of Solids 193 (2024) 105912. (基于能量变分提出了应变能密度极大原理(w_max Principle),检验了w_max Principle指导高强韧金属材料设计的可靠性和优越性；探讨了该原理蕴含的力学、材料物理机制，证实了实验结果、w_max Principle与跨尺度连续介质力学理论的一致性)
3. Y.F. Wang, C.X. Huang, X.L. Ma, J.F. Zhao, F.J. Guo, X.T. Fang, Y.T. Zhu*, Y.G. Wei*. The optimum grain size for strength-ductility combination in metals. International Journal of Plasticity 164 (2023) 103574. (SCI-E高被引论文；澄清应变能密度极限w随微结构尺寸d、强度、塑性的演化规律，发现应变能密度极限极大值w_max及对应的d_c，建立了w_max的预测模型、d_c的物理模型，提出了基于w_max的力学行为评判标准)
4. Y.F. Wang, X.L. Ma, F.J. Guo, Z.F. Zhao, C.X. Huang, Y.T. Zhu, Y.G. Wei*. Strong and ductile CrCoNi medium-entropy alloy via dispersed heterostructure. Materials & Design 225 (2023) 111593. (基于w_max评判力学性能)
5. Y.F. Wang, Y.T. Zhu*, Z.J. Yu, J.F. Zhao, Y.G. Wei*. Hetero-zone boundary affected region: A primary microstructural factor controlling extra work hardening in heterostructure. Acta Materialia 241 (2022) 118395. (建立了三维塑性应变梯度的背应力模型、考虑界面影响区力学效应的应变梯度塑性模型)
6. Y.F. Wang, Y.G. Wei*, Z.F. Zhao, H. Long, Z.Y. Lin, F.J. Guo, Q. He, C.X. Huang*, Y.T. Zhu. Activating dispersed strain bands in tensioned nanostructure layer for high ductility: the effects of microstructure inhomogeneity. International Journal of Plasticity 149: 103159 (2022). (揭示了异构诱导去局域化变形的机制与原理)
7. Y.F. Wang, Y.T. Zhu, X.L. Wu, Y.G. Wei, C.X. Huang. Inter-zone constraint modifies the stress-strain response of the constituent layer in gradient structure. Science China Materials 64: 3114-3123 (2021). (从“异质基元交互作用重塑基元本构行为”的角度创新解读异构诱导强韧化的原理)
8. Y.F. Wang, C.X. Huang, Y.S. Li, F.J. Guo, Q. He, M.S. Wang, X.L. Wu, R.O. Scattergood, Y.T. Zhu. Dense dispersed shear bands in gradient-structured Ni. International Journal Plasticity 124: 186-198 (2020). (揭示了以弥散应变带为媒介的异构诱导韧化效应与机制)
9. Y.F. Wang, C.X. Huang, X.T. Fang, H.W. Höppel, M. Göken, Y.T. Zhu. Hetero-deformation induced (HDI) hardening does not increase linearly with strain gradient. Scripta Materialia 174: 19-23 (2020). (SCI-E高被引论文, 首次实验量化提取出单个微/纳米界面的力学效应)
10. Y.F. Wang, C.X. Huang, Z.K. Li, X.T. Fang, M.S. Wang, Q. He, F.J. Guo, Y.T. Zhu. Shear band stability and uniform elongation of gradient structured materials: Role of lateral constraint. Extreme Mechanics Letter 37: 100686 (2020). (揭示了异构材料的尺寸效应与机制)
11. Y.F.Wang, M.S. Wang, X.T. Fang, F.J. Guo, H.Q. Liu, R.O. Scattergood, C.X. Huang, Y.T. Zhu. Extra strengthening in a coarse/ultrafine grained laminate: Role of gradient interfaces. International Journal Plasticity 123: 196-207 (2019). (揭示异构材料的额外强化效应，提出界面几何必需位错密度的计算模型)
12. C.X. Huang†, Y.F. Wang† (共同一作), X.L. Ma, S. Yin, H.W. Höppel, M. Göken, X.L. Wu, H.J. Gao, Y.T. Zhu. Interface affected zone for optimal strength and ductility in heterogeneous laminate. Mater. Today 21: 713-719 (2018). (SCI-Expanded前1%高被引论文, 发现并提出“界面影响区”概念，建立界面影响区及其特征尺寸的理论模型)

Selected Patents：

1. CN, ZL 2017 1 0149764.0  
2.  JP, 特许第6943513号
3. CN, ZL 2017 1 0149466.1
4. CN, ZL 2017 1 1173272.1
5. CN, ZL 2019 1 0510364.7