张锴教师主页

个人简介 Personal Profile 张锴，同济大学航空航天与力学学院副教授、博导。兼任香港科技大学(广州)霍英东研究院顾问、《应用力学学报》青年编委、上海市力学学会教育工作委员会秘书长、上海市航空工业标准化技术委员会委员等职。长期从事锂离子电池电极材料退化的基础力学理论与应用研究。获评上海市力学学会优秀青年学者，入选上海市晨光人才计划。主持和参与国家自然科学基金、中国航发商发联合创新计划项目、航空科学基金民发专项、国家重点研发计划课题和上海市自然科学基金等项目近10项。与中国船舶集团第七〇四研究所、航天科技集团公司第八研究院第八O五研究所、中国航发商发等企业开展广泛的合作研究。截至2023.6，在Int J Solids Struct、Int J Mech Sci、Int J Impact Eng、Eur J Mech - A/Solids、J Energy Storage 和Electrochim Acta 等知名期刊发表SCI论文50余篇，其中第一/通讯作者论文29篇，1篇论文入选ESI高被引论文，受Springer出版社邀请出版英文专著章节1篇，作为起草工作小组成员参与1项国家标准的制定，授权专利2项。 研究方向Research Directions 固体力学,新形态交叉力学 2. 机电结构优化与控制 研究内容：在对机电结构进行分析和优化的基础上，运用控制理论进行结构参数的调整，使结构性能满足设计要求。1. 仿生结构材料拓扑优化设计, 仿生机械设计 研究内容：以仿生结构为研究对象，运用连续体结构拓扑优化设计理论和方法，对多相仿生结构(机构)材料进行2. 机电结构优化与控制 研究内容：在对机电结构进行分析和优化的基础上，运用控制理论进行结构参数的调整，使结构性能满足设计要求。1. 仿生结构材料拓扑优化设计, 仿生机械设计 研究内容：以仿生结构为研究对象，运用连续体结构拓扑优化设计理论和方法，对多相仿生结构(机构)材料进行整体布局设计。 整体布局设计。 科研项目 国家自然科学基金-青年科学基金项目，基于热力学的硅电极自限制锂化力-化耦合机理研究上海市教育委员会-“晨光计划”项目，基于粘塑性理论的硅电极高倍率充放电方法研究上海市自然科学基金项目，外加机械载荷调控增强硅负极锂离子电池循环性能及其机理研究中国船舶集团第七〇四研究所-XXXX性能计算  研究成果 [1]    Zhang K, Zhou J, Tian T, Kai Y,Li Y*, Zheng B*, Yang F*. Cycling-induced damage of silicon-based lithium-ionbatteries: Modeling and experimental validation. International Journal of Fatigue, 2023, 172: 107660.[2]    Zhang K, Hüger E*, Li Y, SchmidtH, Yang F*. Review and stress analysis on the lithiation onset of amorphoussilicon films. Batteries, 2023, 9.2:105.[3]    Zhang K, Zhou J, Yang F, ZhangY, Pan Y, Zheng B, Li Y*, Yang F*. A stress-control charging method withmulti-stage currents for silicon-based lithium-ion batteries: Theoreticalanalysis and experimental validation. Journalof Energy Storage, 2022, 56: 105985.[4]    Zhang K, Li Y*, Zheng B, YangF*. A free volume-based analytical model for plastic flow in thin-walledsilicon structures of lithium-ion batteries. Acta Mechanica, 2022, 233(2): 561-578.[5]    Zhang K, Li Y, Wang F, Zheng B*, Yang F*, Lu D. An analytical model forlithiation-induced concurrent plastic flow and phase transformation in acylindrical silicon electrode, InternationalJournal of Solids and Structures, 2020, 202: 87-98. [6]    Zhang K, Zheng B*, Yang F*, LiY. Analysis of a cylindrical silicon electrode with a pre-existing crack:Path-independent Ĵ-integral, International Journal of Mechanical Sciences,2020, 177: 105602. [7]    Zhang K, Zhang Y, Zhou J, Li Y,Zheng B, Yang F, Kai Y. A stress-based charging protocol for silicon anode inlithium-ion battery: Theoretical and experimental studies. Journal of Energy Storage, 2020, 32: 101765.[8]    Zhang K, Chen J, Li Y, Liu D*,Zheng B*, Kai Y. Rate-dependent lithiation-induced failure modes of acylindrical core-shell electrode. Resultsin Physics, 2020, 16: 103018. [9]    Zhang K, Zheng B*. Effect ofIrreversible Electrochemical Reaction on Diffusion and Diffusion-InducedStresses in Spherical Composition–Gradient Electrodes, Zeitschrift fur Naturforschung A, 2019, 75(1): 55-63. [10] Zhang K, Li Y, Wang F, ZhengB*, Yang F*. Stress effect on self-limiting lithiation in silicon-nanowireelectrode. Applied Physics Express,2019, 12(4): 045004.[11] Zhang K, Li Y, Wang F, Zheng B,Yang F. A phase-field study of the effect of local deformation velocity onlithiation-induced stress in wire-like structures. Journal of Physics D Applied Physics, 2019, 52(14): 145501.[12] Zhang K*, Li Y, Wu J, Zheng B,Yang F*, Lithiation-induced buckling of wire-based electrodes in lithium-ionbatteries: A phase-field model coupled with large deformation. International Journal of Solids andStructures, 2018, 144: 289-300.[13] Zhang K, Li Y, Zheng B, et al.Large deformation analysis of diffusion-induced buckling of nanowires inlithium-ion batteries. InternationalJournal of Solids and Structures, 2017, 108: 230-243.[14] Zhang K, Li Y, Zheng B.Influence of Maximum Lithium Ion Concentration in Composition-GradientElectrodes on Diffusion-Induced Stresses and Electrochemical Performances. Journal of The Electrochemical Society, 2015,162(9): A1873-A1878.[15] Zhang K, Li Y, Zheng B. Effectsof concentration-dependent elastic modulus on Li-ions diffusion anddiffusion-induced stresses in spherical composition-gradient electrodes. Journal of Applied Physics, 2015,118(10): 105102.[16] Zhang K, Li Y, Zheng B.Modeling of diffusion-induced stresses of spherical composition-gradientelectrodes in lithium-ion batteries. TheEuropean Physical Journal Applied Physics, 2015, 70(1): 10404. [17] HuangH, Li Y, Xue Y, Zhang K*, YangF*. A deep learning approach for solving diffusion-induced stress inlarge-deformed thin film electrodes. Journalof Energy Storage, 2023, 63: 107037.[18] LiY, Zhang K*, Pan Y, Yang F*.Anisotropic behavior in the lithiation of a silicon nanopillar. Journal of Energy Storage, 2023, 57:106271.[19] LiY, Zhang K*,Yang F*. Generalized Theory for DISes in a Large Deformed Solid. InternationalJournal of Applied Mechanics, 2022, 14(4): 2250024.[20] LiY, Zhang K*, Yang F*. Effects ofstress-assisted migration on potentiostatic intermittent titration technique(PITT) in spherical particles. ElectrochimicaActa, 2022, 425: 140732.[21] WangF, Zhang K*, Zheng B*. The non-local effectsinduced by rapid transient mass diffusion in a spherical silicon electrode oflithium-ion batteries. Acta MechanicaSolida Sinica, 2022, 35(1): 174-184.[22] LiY, Zhang K*, Pan Y, Yang F*.Anisotropic behavior in the lithiation of a silicon nanopillar. Journal ofEnergy Storage, 2023, 57: 106271.[23] ZhangY, Zhan S, Zhang K*, Zheng B*, Lyu L. Bucklingbehavior of a wire-like electrode with a concentration-dependent elasticmodulus based on a deformed configuration. EuropeanJournal of Mechanics-A/Solids, 2020, 85: 104111.[24] WangF, Zhang K*, Zheng B*. A developed expression of chemical potential for fastdeformation in nanoparticle electrodes of lithium-ion batteries, Nanoscale Research Letters, 2019, 14(1): 262.[25] LyuL, Zheng B*, Zhang K*, Wang F,Zhan S. Effect of stress-dependent activation enthalpy on electrochemicalreaction and diffusion-reaction-induced stress in spherical electrodes. Results in Physics, 2019, 14: 102407.[26] LiuJ, Zheng B*, Zhang K*, YangB, Yu X. Ballistic performance and energy absorption characteristics of thinnickel- based alloy plates at elevated temperatures. International Journal of Impact Engineering, 2019, 126: 160-171.[27] KaiY, Zheng B*, Zhang K*, Xu W,Yang N. Exact and asymptotic solutions to magnetohydrodynamic flow over anonlinear stretching sheet with a power-law velocity by the homotopyrenormalization method, Physics of Fluids,2019, 31(6): 063606.[28] PengY, Y Li, Zheng B*, Zhang K*,Xu Y. Influence of local velocity on Diffusion-induced stress and axialreaction force in a hollow cylindrical electrode of lithium-ion batteries. Acta Physica Sinica, 2018, 67(7): 070203.[29] XuY, Zheng B*, Zhang K*, PengY, Wang F. Effect of combining local velocity and chemical reaction on theinteraction between diffusion and stresses in large deformed electrodes. AIP Advances, 2019, 9(10), 105103. 学生信息 当前位置：教师主页 > 学生信息 入学日期 所学专业 学号 学位 招生信息 当前位置：教师主页 > 招生信息 招生学院 招生专业 研究方向 招生人数 推免人数 考试方式 招生类别 招生年份