张晓鹏,工程力学系副教授, 博士研究生导师。
先后获得两个工学博士学位(2015中国大连理工大学、2018日本广岛大学)。国际结构与多学科优化学会会员,中国力学学会会员,辽宁省力学学会理事。获2020年度教育部自然科学一等奖,获2022年第七届中国创新挑战赛优胜奖。入选大连市高层次人才(高端人才),大连市青年科技之星,大连理工大学星海人才培育计划(星海优青、星海骨干)。
主要从事 考虑力学与多物理场超材料优化设计、考虑动力学性能的宏微观结构优化, 考虑不确定性的结构拓扑优化,减振材料与功能结构优化、智能材料与结构优化设计等方面的研究,共发表国际SCI期刊论文40余篇,第一作者出版学术专著《结构动力学拓扑优化理论与方法》一部。 多篇论文发表于本领域重要国际期刊,包括:Comput. Methods Appl. Mech. Engrg.,Int. J. Numer. Meth. Eng., Materials & Design,Struct Multidiscip O,J Sound Vib ,Smart Mater Struct等。担任Comput. Methods Appl. Mech. Engrg., Materials & Design,Int. J. Numer. Meth. Eng. 等多个重要国际期刊审稿人,担任《应用力学学报》青年编委,SCI期刊《International Journal of Smart and Nano Material》 青年编委,《Frontiers in Physics》Review Editor。
科研成果简介:
近年来一直从事结构动力学优化及相关研究,包括:结构动力学拓扑优化方法、动力学/机械超材料设计、多物理场耦合结构优化、面向先进制造的结构设计与工程应用等。多篇论文发表于本领域权威期刊,并被选为封面论文。研究成果被国际结构与优化学会历任主席 Olhoff 院士 、程耿东院士、Sigmund院士, 铁木辛柯奖章得主 Reddy院士,中国科学院 胡海岩院士、张卫红院士,美国工程院Paulino院士,澳大利亚工程院 YM Xie院士,欧洲科学院CZ Zhang院士,加拿大工程院 L Cheng院士,韩国工程院SK Youn院士等多位国际著名学者的引用和大篇幅正面评价。
主要研究领域:
更多内容参见“科学研究-研究领域”页面
团队温暖和谐,师生积极进取。
目前指导博士研究生4人,硕士研究生7人。
多位研究生曾获辽宁省优秀毕业生、大连市优秀毕业生,校优秀硕士学位论文、校优秀研究生、优秀学生干部等称号。
热烈欢迎力学、机械、材料、物理等相关学科感兴趣的同学咨询、加入我们课题组:zhangxiaopeng@dlut.edu.cn
微信号:zhangxiaopeng230481
科研奖励与荣誉:
2020 教育部自然科学一等奖(排名第三)
2021 大连市高层次人才(高端人才)
2020 大连市青年科技之星
2019 大连理工大学星海优青
2019 大连理工大学星海骨干考核优秀(全校共六人)
2019 钱令希力学奖一等青年教师奖
2018 大连理工大学星海骨干
2016年度 辽宁省优秀博士论文(全省20人)
工作经历:
2020.1-今 大连理工大学 工程力学系 副教授/博导
2015.5-2019.12 大连理工大学 工程力学系 讲师
2015.5-2019.3 大连理工大学 船舶与海洋工程博士后流动站 博士后
2016.11-2018.11 日本广岛大学 运输与环境系统系 研究员/博士后
学习经历:
2009.9-2015.4 大连理工大学 工程力学系 计算力学专业 工学博士 导师:亢战 教授 (被评选为辽宁省优秀博士论文、辽宁省优秀毕业生)
2016.11-2018.09日本广岛大学,运输与环境系统专业,获得工学博士学位 导师:Takezawa教授
2005.9-2009.8 大连理工大学 工程力学系 工程力学专业 工学学士
主要科研项目:
1) 负责国家自然科学基金面上项目1项 (2023-2026);
2) 负责国家自然科学基金青年基金1项 (2016-2019);
3) 负责中国博士后科学基金特别资助1项 (2018-2019);
4) 负责中国博士后科学基金面上项目1项 (2015-2017);
5) 负责上海交通大学机械系统与振动国家重点实验室开放课题1项 (2016-2017);
6) 负责辽宁省博士启动基金1项 (2016-2018);
7)参与国家自然科学基金重点项目2项;
近期主要论著:
专著:
《结构动力学拓扑优化理论与方法》,张晓鹏,亢战。大连理工大学出版社, 2020。
论文: (2012-2023)
[1] K. Liang, Y. Wang, Y. Luo, A. Takezawa, X. Zhang, Z. Kang, Programmable and multistable metamaterials made of precisely tailored bistable cells, Materials & Design, (2023) 111810.
[2] X. Zhang, Y. Li, Y. Wang, Y. Luo, Ultra-wide low-frequency bandgap design of acoustic metamaterial via multi-material topology optimization, Composite Structures, 306 (2023) 116584.
[3] 梁宽, 付莉莉, 张晓鹏, 基于材料场级数展开的结构动力学拓扑优化, 航空学报, 43 (2022) 226002.
[4] Y. Zhu, Y. Wang, X. Zhang, Z. Kang, A new form of forbidden frequency band constraint for dynamic topology optimization, Structural and Multidisciplinary Optimization, 65 (2022) 123.
[5] H. Zhang, A. Takezawa, X. Ding, X. Zhang, S. Xu, H. Li, S. Nozawa, S. Nishiwaki, Robust topology optimization of biodegradable composite structures under uncertain degradation rates, Composite Structures, 291 (2022) 115593.
[6] H. Zhang, X. Ding, W. Ni, Y. Chen, X. Zhang, H. Li, Concurrent Topology Optimization of Composite Plates for Minimum Dynamic Compliance, Materials, 15 (2022) 538.
[7] Y. Wang, Z. Kang, X. Zhang, A velocity field level set method for topology optimization of piezoelectric layer on the plate with active vibration control, Mechanics of Advanced Materials and Structures, (2022) 1-14.
[8] K. Liang, J. He, Z. Jia, X. Zhang, Topology optimization of magnetorheological smart materials included PnCs for tunable wide bandgap design, Acta Mechanica Sinica, 38 (2022) 421525.
[9] Y. Li, Y. Luo, X. Zhang, Topological design of phononic crystals for multiple wide band gaps, Journal of Sound and Vibration, 529 (2022) 116962.
[10] Z. Jia, Y. Luo, A. Takezawa, X. Zhang, Topology optimization for realizing tailored self‐collimation in phononic crystals, International Journal for Numerical Methods in Engineering, 123 (2022) 4170-4182.
[11] H. Guo, K. Ichikawa, H. Sakai, H. Zhang, X. Zhang, K. Tsuruta, K. Makihara, A. Takezawa, Numerical and experimental analysis of additively manufactured particle dampers at low frequencies, Powder Technology, 396 (2022) 696-709.
[12] X. Zhang, J. Xing, P. Liu, Y. Luo, Z. Kang, Realization of full and directional band gap design by non-gradient topology optimization in acoustic metamaterials, Extreme Mechanics Letters, 42 (2021) 101126.
[13] X. Zhang, Y. Luo, Y. Yan, P. Liu, Z. Kang, Photonic band gap material topological design at specified target frequency, Advanced Theory and Simulations, 4 (2021) 2100125.
[14] X. Zhang, Y. Li, Y. Wang, Z. Jia, Y. Luo, Narrow-band filter design of phononic crystals with periodic point defects via topology optimization, International Journal of Mechanical Sciences, 212 (2021) 106829.
[15] X. Zhang, Z. Jia, Y. Luo, Y. Wang, P. Liu, Z. Kang, A Precisely‐Controlled Multichannel Phononic Crystal Resonant Cavity, Advanced Theory and Simulations, 4 (2021) 2100250.
[16] H. Zhang, A. Takezawa, X. Ding, H. Guo, W. Ni, X. Zhang, Topology optimization of composite macrostructures comprising multi-phase viscoelastic composite microstructures for enhanced structural damping, Composite Structures, 278 (2021) 114712.
[17] Y. Yan, P. Liu, X. Zhang, Y. Luo, Photonic crystal topological design for polarized and polarization-independent band gaps by gradient-free topology optimization, Optics Express, 29 (2021) 24861-24883.
[18] P. Liu, X. Zhang, Y. Luo, Topological design of freely vibrating bi-material structures to achieve the maximum band gap centering at a specified frequency, Journal of Applied Mechanics, 88 (2021).
[19] P. Liu, Y. Yan, X. Zhang, Y. Luo, Z. Kang, Topological design of microstructures using periodic material-field series-expansion and gradient-free optimization algorithm, Materials & Design, 199 (2021) 109437.
[20] P. Liu, Y. Yan, X. Zhang, Y. Luo, A MATLAB code for the material-field series-expansion topology optimization method, Frontiers of Mechanical Engineering, 16 (2021) 607-622.
[21] K. Liang, Y. Luo, Z. Liu, X. Zhang, Z. Kang, Multi-electrode layout design of electrorheological composite plates considering energy consumption in semi-active control, Thin-Walled Structures, 165 (2021) 108001.
[22] M. He, X. Zhang, L. dos Santos Fernandez, A. Molter, L. Xia, T. Shi, Multi-material topology optimization of piezoelectric composite structures for energy harvesting, Composite Structures, 265 (2021) 113783.
[23] J. He, J. Sun, J. Fan, Z. Jia, X. Zhang, Optimal Designs of Phononic Crystal Microstructures Considering Point and Line Defects, Symmetry, 13 (2021) 1993.
[24] 张晓鹏, 康柯, 杨东生, 基于相场描述的拉压不对称强度结构拓扑优化 Phase-field based topology optimization with Drucker-Prager yield stress constraints, 计算力学学报, (2020) 670-676.
[25] 林晔, 张晓鹏, 胡骏, 亢战, 压电智能结构拓扑优化研究进展, 固体力学学报, 41 (2020) 391-408.
[26] J. Zhan, Y. Luo, X. Zhang, Z. Kang, A general assessment index for non-probabilistic reliability of structures with bounded field and parametric uncertainties, Computer Methods in Applied Mechanics and Engineering, 366 (2020) 113046.
[27] A. Takezawa, X. Zhang, T. Tanaka, M. Kitamura, Topology optimisation of a porous unit cell in a fluid flow considering Forchheimer drag, International Journal of Computational Fluid Dynamics, 34 (2020) 50-60.
[28] A. Takezawa, A.C. To, Q. Chen, X. Liang, F. Dugast, X. Zhang, M. Kitamura, Sensitivity analysis and lattice density optimization for sequential inherent strain method used in additive manufacturing process, Computer Methods in Applied Mechanics and Engineering, 370 (2020) 113231.
[29] X. Zhang, A. Takezawa, Z. Kang, A phase-field based robust topology optimization method for phononic crystals design considering uncertain diffuse regions, Computational Materials Science, 160 (2019) 159-172.
[30] X. Zhang, A. Takezawa, Z. Kang, Robust topology optimization of vibrating structures considering random diffuse regions via a phase-field method, Computer Methods in Applied Mechanics and Engineering, 344 (2019) 766-797.
[31] A. Takezawa, X. Zhang, Y. Koizumi, Numerical study on the effective stiffness of topology-optimized lattice structures made of orthotropic crystal grains with optimal orientation, Computational Materials Science, 159 (2019) 202-209.
[32] A. Takezawa, X. Zhang, M. Kitamura, Optimization of an additively manufactured functionally graded lattice structure with liquid cooling considering structural performances, International Journal of Heat and Mass Transfer, 143 (2019) 118564.
[33] A. Takezawa, X. Zhang, M. Kato, M. Kitamura, Method to optimize an additively-manufactured functionally-graded lattice structure for effective liquid cooling, Additive Manufacturing, 28 (2019) 285-298.
[34] A. Takezawa, T. Yamamoto, X. Zhang, K. Yamakawa, S. Nakano, M. Kitamura, An objective function for the topology optimization of sound-absorbing materials, Journal of Sound and Vibration, 443 (2019) 804-819.
[35] X. Suo, Z. Kang, X. Zhang, Y. Wang, Bi-material Topology Optimization Using Analysis Mesh-Independent Point-Wise Density Interpolation, Acta Mechanica Solida Sinica, 32 (2019) 698-712.
[36] Z. Liu, S. Cho, A. Takezawa, X. Zhang, M. Kitamura, Two-stage layout–size optimization method for prow stiffeners, International Journal of Naval Architecture and Ocean Engineering, 11 (2019) 44-51.
[37] X. Zhang, A. Takezawa, Z. Kang, Topology optimization of piezoelectric smart structures for minimum energy consumption under active control, Structural and Multidisciplinary Optimization, 58 (2018) 185-199.
[38] X. Zhang, J. He, A. Takezawa, Z. Kang, Robust topology optimization of phononic crystals with random field uncertainty, International Journal for Numerical Methods in Engineering, 115 (2018) 1154-1173.
[39] A. Takezawa, K. Yonekura, Y. Koizumi, X. Zhang, M. Kitamura, Isotropic Ti–6Al–4V lattice via topology optimization and electron-beam melting, Additive Manufacturing, 22 (2018) 634-642.
[40] A. Takezawa, K. Takenaka, X. Zhang, Inverse analysis of giant macroscopic negative thermal expansion of Ca2RuO4− y ceramics based on elasticity and structural topology optimization, Applied Physics Express, 11 (2018) 055801.
[41] J. Hu, X. Zhang, Z. Kang, Layout design of piezoelectric patches in structural linear quadratic regulator optimal control using topology optimization, Journal of Intelligent Material Systems and Structures, 29 (2018) 2277-2294.
[42] M. Li, Y. Niu, H. Wu, X. Zhang, Y. Luo, Z. Kang, Wrinkling and wrinkling-suppression in graphene membranes with frozen zone, Thin Solid Films, 638 (2017) 345-353.
[43] X. Zhang, Z. Kang, W. Zhang, Robust topology optimization for dynamic compliance minimization under uncertain harmonic excitations with inhomogeneous eigenvalue analysis, Structural and Multidisciplinary Optimization, 54 (2016) 1469-1484.
[44] X. Zhang, Z. Kang, Vibration suppression using integrated topology optimization of host structures and damping layers, Journal of Vibration and Control, 22 (2016) 60-76.
[45] 王睿, 张晓鹏, 吴良武, 亢战, 考虑瞬态响应的薄板结构阻尼材料层拓扑优化, 工程力学, 32 (2015) 1-7, 14.
[46] X. Zhang, Z. Kang, Topology optimization of magnetorheological fluid layers in sandwich plates for semi-active vibration control, Smart Materials and Structures, 24 (2015) 085024.
[47] X. Zhang, Z. Kang, M. Li, Topology optimization of electrode coverage of piezoelectric thin-walled structures with CGVF control for minimizing sound radiation, Structural and Multidisciplinary Optimization, 50 (2014) 799-814.
[48] X. Zhang, Z. Kang, Dynamic topology optimization of piezoelectric structures with active control for reducing transient response, Computer Methods in Applied Mechanics and Engineering, 281 (2014) 200-219.
[49] X. Zhang, Z. Kang, Topology optimization of piezoelectric layers in plates with active vibration control, Journal of Intelligent Material Systems and Structures, 25 (2014) 697-712.
[50] Y. Wang, Z. Luo, X. Zhang, Z. Kang, Topological design of compliant smart structures with embedded movable actuators, Smart Materials and Structures, 23 (2014) 045024.
[51] 王睿, 张晓鹏, 亢战, 以动柔度为目标的结构阻尼材料层拓扑优化, 振动与冲击, 32 (2013) 36-40.
[52] X. Zhang, Z. Kang, Topology optimization of damping layers for minimizing sound radiation of shell structures, Journal of Sound and Vibration, 332 (2013) 2500-2519.
[53] X. Meng, M. Li, Z. Kang, X. Zhang, J. Xiao, Mechanics of self-folding of single-layer graphene, Journal of Physics D: Applied Physics, 46 (2013) 055308.
[54] Z. Kang, X. Zhang, S. Jiang, G. Cheng, On topology optimization of damping layer in shell structures under harmonic excitations, Structural and Multidisciplinary Optimization, 46 (2012) 51-67.
