吴林志

　　吴林志，教授、博士生导师、曾任哈尔滨工程大学副校长。国家级高层次人才，从事超轻质复合材料及其多功能结构、轻质防护结构、声热隐身超材料等方面的研究工作。获国家自然科学二等奖、教育部科技进步基础类一等奖、黑龙江省自然科学一等奖等多项国家级/省部级奖项。承担国家自然科学基金重点项目等多项课题。在国内外重要学术刊物共发表SCI收录的学术论文200 余篇，由科学出版社出版了有关复合材料点阵结构的首部专著，获授权的发明专利30余项。带领的团队针对航天、船舶等领域对先进复合材料及结构的需求，开展了功能梯度材料断裂力学、新型轻质结构设计/制备/表征/评价等方面的研究工作，是国际上最先制备出超轻复合材料点阵结构的少数几家单位之一，并对其开展了系统的研究，平压性能超过国际水平，填补了Ashby材料选材图的空白。

　　Linzhi Wu is a Professor of Mechanics and Materials at Harbin Engineering University (HEU). Prof Wu is a Distinguished Young Scholar of China. Wu’s research focuses on the theoretical and experimental investigation of lightweight composite sandwich structures, including their design, processing, fabrication, structure and properties and in their engineering and industrial applications. Other major areas of interest include micromechanics of composites, fracture mechanics of functionally graded materials, elastic wave propagation and control as well as metamaterials. He has published over 260 research papers and forty national invention patents.

　　1981.9-1985.7 吉林大学数学系力学专业　　　学士
　　1985.9-1988.6 哈尔滨工业大学固体力学　　　硕士
　　1990.3-1992.11 哈尔滨工业大学固体力学专业　博士

　　Wu obtained his bachelor degree in Mechanics form Jilin University in 1985 and a Ph.D. in Solid Mechanics from Harbin Institute of Technology (HIT) in 1992. He worked at Center for Composite Materials, HIT from 1992 to 1994 as Lecturer, from 1994 to 1997 as Associate Professor and from 1997 to 2015 as Professor. Linzhi joined HEU in 2015 and currently is a Professor of Mechanics and Materials at School of Aerospace and Civil Engineering, HEU.

　　1988.7-1994.7  哈工大航天学院复合材料研究室　助教、讲师
　　1994.7-1997.7  哈工大航天学院复合材料研究室　副教授
　　1997.8-2015.9  哈工大复合材料与结构研究所　　教授
　　1999.5-2015.9  哈工大复合材料与结构研究所　　博导
　　2006.2-2015.9  哈工大理学院　　　　　　　　　院长
　　2015.9-             哈尔滨工程大学　　　　　　　　副校长

　　Wu has been a standing member of the Executive Committee (8th and 9th, 2006-2014) of The Chinese Society of Theoretical and Applied Mechanics. He has been the vice director of the Executive Committee (6th to 8th 1998-2010) of the Solid Mechanics Division, of The Chinese Society of Theoretical and Applied Mechanics. He currently is a standing member of the Executive Committee (11th, 2019-) of The Chinese Society of Theoretical and Applied Mechanics.

　　1988.7-1994.7 Composite Materials Laboratory, School of Astronautics, Harbin Institute of Technology. Teaching assistant, Lecturer
　　1994.7-1997.7 Composite Materials Laboratory, School of Astronautics, Harbin Institute of Technology. Associate professor
　　1997.8-2015.9 Institute of Composites and Structures, Harbin Institute of Technology. Professor
　　1999.5-2015.9 Institute of Composites and Structures, Harbin Institute of Technology. Doctoral supervisor
　　2006.2-2015.9 School of Science, Harbin Institute of Technology. Dean
　　2015.9 To this day Harbin Engineering University. Vice-principal     

　　超轻质复合材料及其多功能结构设计制备及性能表征
　　轻质防护材料与结构的设计制备及性能表征
　　声热隐身超材料的设计与制备

　　Design, preparation and properties characterization of ultra-lightweight composites with multifunctional structure
　　Design, preparation and characterization of lightweight protective materials and structures
　　Design and preparation of acousto-thermal stealth metamaterials

　　 
　　2018.1-2021.12  轻质储热控温多功能结构的力学性能与控温机理研究  国家自然科学基金面上项目
　　  
　　2015.1-2019.12  金属点阵结构的低成本制备及力学性能表征  国家自然科学基金重点项目
　　
　　2011.1-2015.12  点阵复合材料结构的多功能一体化构建理论  国家科技部973项目
　　
　　2011.1-2013.12  含夹杂复合材料有效性能界限的新方法  国家自然科学基金面上项目
　　2009.1-2012.12  集电源、热控和结构于一体的多功能结构研究  国家自然科学基金重大研究计划
　

　　
　　2018.1-2021.12  Study on mechanical properties and temperature control mechanism of lightweight heat storage and　temperature control multifunctional structure   General Project of National Natural Science Foundation of China
　　
　　2015.1-2019.12 Low cost preparation and mechanical properties characterization of metal lattice structures  National Natural Science Foundation of China
　　
　　2011.1-2015.12  Theory of multifunctional integration construction of lattice composite structures .Project 973 of Ministry of Science and Technology of China
　　
　　2011.1-2013.12 A new method for effective property limits of composite materials containing inclusion. General Project of National Natural Science Foundation of China
　　2009.1-2012.12 Research on multifunctional structure integrating power supply, thermal control and structure. The National Natural Science Foundation of China
　

　　欢迎如下相关专业的青年才俊攻读博士和硕士学位：
　　力学、机械、土木、物理、数学、飞行器设计、材料等专业

　　The following young talents are welcome to study for PhD and Master's degree:  
　　Major in mechanics, mechanics, civil engineering, physics, mathematics, aircraft design, materials, etc

　　《材料力学》
　　《力学导论》

　　Mechanics of materials
　　Introduction to Mechanics

　　《细观力学》
　　《结构轻量化设计基础》

　　Micromechanics  
　　Fundamentals of Structural Lightweight Design

　　1.教育部首批新工科项目　2018　主动适应和引领新经济，四维度推进工科人才培养模式改革探索与实践　兰海、蒋鲲、吴华洋、张红岩、吕开东、史波、刘志强、孙荣平、毛继泽、任正义、耿敬、路勇、孙建国、董国君
　　2.教育部第二批新工科项目　2020　深化新工科产教融合，创新协同育人培养模式　孙建国、高迪、张龙、卢先和、吕开东、史波、陈弘、毛继泽、孙荣平、张红岩
　　3.省级重点委托项目　2020　船海领域未来技术学院的探索与实践    耿敬、孙荣平、骆毅、梁爽
　　4.省级一般教改项目　2017　新工科背景下工科优势高校构建学科交叉融合人才培养模式的研究与探索　兰海、孙世钧、张红岩、井维亮
　　5.2019年度黑龙江省高等教育教学成果奖特等奖　新工科背景下工科优势高校构建学科交叉融合人才培养模式的研究与实践　吴林志、兰海、孙荣平、耿敬、张红岩、骆毅、孙梦楠、李勇、陈大龙
　
　　1.The first batch of new engineering projects of the Ministry of Education.2018. Actively adapt to and lead the new economy, and promote the exploration and practice of the reform of the training mode of engineering talents from four dimensions  
　　2.The second batch of new engineering projects of the Ministry of Education.2020. Deepen the integration of industry and education in new engineering sectors and innovate collaborative training models
　　3.Provincial key entrusted projects.2020. Exploration and practice of future technical college in Marine field
　　4.Provincial general education reform project. 2017. Research and exploration on the construction of interdisciplinary and integrated talent training mode in engineering superior universities under the new engineering background  
　　5.The 2019 Heilongjiang Higher Education Teaching Achievement Award Special Award

　　曾任国务院学位委员会第六届学科评议组力学组成员
　　曾任国家自然科学基金委员会第十一届、第十二届数理科学部专家评审组成员
　　曾任中国力学学会第八届、第九届理事会常务理事
　　曾任中国力学学会第六届、第七届、第八届、第九届固体力学专业委员会副主任
　　现任中国力学学会第十一届理事会常务理事
　　现任Acta Mechanica Sinica、力学学报、固体力学学报、计算力学学报等编委

　　He was once a member of the Mechanics Group of the Sixth Discipline Evaluation Group of the Academic Degrees Committee of the State Council  
　　He was once a member of the expert review group of the 11th and 12th sessions of the Department of Mathematical and Physical Sciences of the National Natural Science Foundation of China  
　　He was the executive director of the 8th and 9th Council of Chinese Society of Mechanics  
　　He was the deputy director of the sixth, seventh, eighth and ninth professional committee of solid mechanics of Chinese Society of Mechanics  
　　He is now the executive director of the 11th Council of Chinese Society of Mechanics  
　　He is currently Editorial Board Member of ACTA Mechanica SINICA, Journal of Solid Mechanics, and Journal of Computational Mechanics

　　1.全金属中空点阵 蜂窝混杂夹芯结构及其嵌锁制备方法  吴林志 胡滨 吴倩倩 魏光涛  CN201710500960.8
　　2.一种中空金字塔型点阵夹芯板及其嵌锁制备方法  吴林志 胡滨 马力 杨雯  CN201710500981.X
　　3.一种导热型聚合物基复合材料及其制备方法  吴林志 于国财  CN201510056156.6
　　4.一种集导热与承载于一体的轻质点阵结构夹芯板及其制备方法  吴林志 于国财 熊健  CN201510056160.2
　　5.一种集导热与承载于一体的轻质格栅结构夹芯板及其制备方法  吴林志 于国财 马力  CN201510056102.X
　　6.纤维增强六角蜂窝结构芯材的一体化成型模具及成型方法  吴林志 殷莎  CN201110304037.X
　　7.点阵夹芯板的芯材及挤压嵌锁制造方法  吴林志 冯丽佳 马力 于国财  CN201310241661.9
　　8.一种基于堆垛的复合材料点阵夹芯板及其制备方法  吴林志 殷莎 彭亮  CN201110246876.0
　　9.空心圆管金字塔型全复合材料点阵夹芯板的制备方法  吴林志 殷莎 马力  CN201010221143.7
　　10.整体加固的复合材料点阵夹芯板及其制备方法  吴林志 吴倩倩 张国旗 马力  CN201010202995.1
　　11.采用预浸纤维束制备复合材料点阵夹芯板的制备方法  吴林志 李明 马力 王兵 杨金水  CN201210310023.3
　　12.一种用于制备纤维增强蛋壳型点阵夹芯板芯子的组装模具  吴林志 熊健 马力 刘加一  CN200910073306.9
　　13.一种金字塔点阵夹芯结构的制备工艺  吴林志 张国旗 马力 泮世东 王兵  CN201110220912.6
　　14. 一种带有横筋的金字塔型点阵夹芯板及制备该芯子的嵌条及制备方法  吴林志 熊健 马力 熊刚 刘加一  CN201110189394.6
　　15. 一种纤维增强复合点阵夹芯板及其制造方法  吴林志 王  兵 金  鑫  CN200710144329.5
　　16. 采用纤维编织预浸布制备复合材料点阵夹芯板的方法  吴林志 熊健 泮世东 彭亮 马力  CN201010522716.X
　　17.一种轻质点阵夹芯板及采用线切割打孔制备该板的方法  吴林志 熊健 马力 赵望安 齐学飞  CN201010281933.4
　　18.一种轻质点阵夹芯板及采用激光切孔制备该板的方法  吴林志 熊健 马力 殷莎 王明亮  CN201010281190.0
　　19. 一种制备金字塔型复合材料点阵夹芯板的混合模具  吴林志 殷莎 马力 李明 王兵  CN201010221112.1
　　20. 柔性植入复合材料的制备方法  吴林志 周涵  CN201910324459.X
　　21. 全碳纤维复合材料蜂窝结构及其制备方法  吴林志 杨志韬 刘鑫 于国财  CN201810958326.3
　　22. 一种用于成组制备带有槽口的倾斜圆管的卡具工装  吴林志 胡滨 熊健 吴倩倩  CN201710502756.X

　　1.An all-metal hollow lattice honeycomb hybrid sandwich structure and a preparation method for interlocking .  CN201710500960.8
　　2.The invention relates to a hollow pyramid lattice sandwich plate and a preparation method for a locking thereof. CN201710500981.X
　　3. The invention discloses a thermal conductive polymer matrix composite material and a preparation method thereof. CN201510056156.6
　　4.The invention relates to a sandwich plate with light lattice structure integrating heat conduction and load bearing and a preparation method thereof . CN201510056160.2
　　5. The invention relates to a sandwich plate with light grid structure which integrates heat conduction and load bearing and a preparation method thereof. CN201510056102.X
　　6. An integrated forming mould and forming method for fiber reinforced hexagonal honeycomb structure core material . CN201110304037.X
　　7. The invention relates to a composite lattice sandwich plate based on stacking and a preparation method thereof. CN201310241661.9
　　8. The invention relates to a composite lattice sandwich plate based on stacking and a preparation method thereof. CN201110246876.0
　　9. Preparation method of hollow tube pyramid full composite lattice sandwich plate . CN201010221143.7
　　10. The whole reinforced composite lattice sandwich plate and a preparation method thereof. CN201010202995.1
　　11. The preparation method of composite lattice sandwich plate by prepreg fiber bundle is presented. CN201210310023.3
　　12. The invention discloses an assembly die for preparing a core of a fiber reinforced eggshell lattice sandwich plate . CN200910073306.9
　　13. The invention relates to a preparation process of pyramid lattice sandwich structure. CN201110220912.6
　　14. The utility model relates to a pyramid lattice sandwich core plate with transverse bars, a strip for preparing the core and a preparation method thereof . CN201110189394.6
　　15. The invention discloses a fiber reinforced composite lattice sandwich plate and a manufacturing method thereof. CN200710144329.5
　　16. The method of preparing composite lattice sandwich plate with fiber braided prepreg cloth is presented . CN201010522716.X
　　17. The invention relates to a light lattice sandwich plate and a method for preparing the plate by wire cutting and punching . CN201010281933.4
　　18. The invention relates to a light lattice sandwich plate and a method for preparing the plate by laser hole cutting . CN201010281190.0
　　19. The utility model relates to a mixing mold for preparing a pyramid type composite lattice sandwich plate. CN201010221112.1
　　20. The preparation method of flexible implant composite material. CN201910324459.X
　　21. Honeycomb structure of carbon fiber composite and preparation method thereof. CN201810958326.3
　　22. The utility model relates to a fixture tool for group preparation of inclined round tubes with notches. CN201710502756.X

序号	专著、译著 和教材名称	出版社名称	出版 年月	本人编写字数/总字数（万字）	第 一 作者	本人排序
1	复合材料点阵结构力学性能表征	科学出版社	2015	28.1	吴林志	1
2	Mechanics of Functionally Graded Materials and Structures	Nova Science Publishers	2012		仲政	2

　　1. Xiong J, Ma L, Wu LZ, et al. (2011) Mechanical behavior of sandwich panels with hollow Al-Si tubes core construction. Materials & Design 32(2): 592-597.
　　2. Zhou ZG, Zhang PW, Wu LZ (2011) Non-local theory solution of a limited-permeable mode-I crack in a piezoelectric/piezomagnetic material plane. ZAMM-ZEITSCHRIFT FUR ANGEWANDTE MATHEMATIK UND MECHANIK 91(3): 192-213.
　　3. Wang B, Wu LZ, Ma L, et al. (2011) Low-velocity impact characteristics and residual tensile strength of carbon fiber composite lattice core sandwich structures. Composites Part B-Engineering 42(4): 891-897.
　　4. Xiong J, Ma L, Wu LZ, et al. (2011) Mechanical behavior and failure of composite pyramidal truss core sandwich columns. Composites Part B-Engineering 42(4): 938-945.
　　5. Li M, Wu LZ, Ma L, et al. (2011) Structural response of all-composite pyramidal truss core sandwich columns in end compression. Composite Structures 93(8): 1964-1972.
　　6. Li M, Wu LZ, Ma L, et al. (2011) Torsion of carbon fiber composite pyramidal core sandwich plates. Composite Structures 93(9): 2358-2367.
　　7. He QL, Wu LZ, Li M, et al. (2011) Energy dissipation and contour integral characterizing fracture behavior of incremental plasticity. Acta Mechanica Sinica 27(2): 251-258.
　　8. Zhou ZG, Liu JY, Wu LZ (2011) Basic solutions of a 3-D rectangular limited-permeable crack or two 3-D rectangular limited-permeable cracks in piezoelectric materials. Meccanica p 1-26.
　　9. Li M, Wu LZ, Ma L, Wang B, Guan ZX (2011) Mechanical Response of All-composite Pyramidal Lattice Truss Core Sandwich Structures. Journal of Materials Science & Technology 27(6): 570-576.
　　10. Liu JY, Zhou ZG, Ma L, Xiong J, Wu LZ (2011) Temperature effects on the strength and crushing behavior of carbon fiber composite truss sandwich cores . Composites Part B-Engineering 42(7): 1860-1866.
　　11. Yin S, Wu LZ, Ma Li (2011) Pyramidal lattice sandwich structures with hollow composite trusses. Composite Structures 93(12): 3104-3111.
　　12. Wu LZ, Yu HJ, Guo LC, et al. (2011) Investigation of stress intensity factors for an interface crack in multi-interface materials using an interaction integral method. Journal of Applied Mechanics- Transactions of the ASME 78(6): 10.1115/1.4003906.
　　13. Li M, Wu LZ, Ma L, Wang B, Guan ZX (2011) Structural design of pyramidal truss core sandwich beams loaded in 3-point bending. Journal of Mechanics of Materials and Structures 6(9): 1255-1266.
　　14. Xiong J, Vaziri A, Ma L, Papadopoulos J, Wu LZ (2012) Compression and impact testing of two-layer composite pyramidal-core sandwich panels. Composite Structures 94(2): 793-801.
　　15. Zhou ZG, Liu JY, Wu LZ (2012) Basic solutions of a 3-D rectangular limited-permeable crack or two 3-D rectangular limited-permeable cracks in piezoelectric materials. Meccanica 47(1): 109-134.
　　16. Zhang GQ, Ma L, Wang B, Wu LZ (2012) Mechanical behaviour of CFRP sandwich structures with tetrahedral lattice truss cores. Composites Part B-Engineering 43(2): 471-476.
　　17. Zhou ZG, Zhang PW, Wu LZ (2012) Basic solutions of a 3D rectangular limited-permeable crack or two 3D rectangular limited-permeable cracks in the piezoelectric/piezomagnetic composite materials. Applied Mathematical Modelling 36(6): 2404-2428.
　　18. Yin S, Wu LZ, Ma L, et al. (2012) Hybrid truss concepts for carbon fiber composite pyramidal lattice structures. Composites Part B-Engineering 43(4): 1749-1755.
　　19. Wang ZY, Ma L, Wu LZ, et al. (2012) Numerical simulation of crack growth in brittle matrix of particle reinforced composites using the xfem technique. Acta Mechanica Solida Sinica 25(1): 9-21.
　　20. Yu HJ, Wu LZ, Guo LC (2012) T-stress evaluations for nonhomogeneous materials using an interaction integral method. International Journal for Numerical Methods in Engineering 90(11):  1393-1413.
　　21. Wu LZ, Pan SD (2012) Bounds on effective magnetic permeability of three-phase composites with coated spherical inclusions. Composites Science and Technology 72(12): 1443-1450.
　　22. Yu HJ, Wu LZ, Li H (2012) T-stress evaluations of an interface crack in the materials with complex interfaces. International Journal of Fracture 177(1): 25-37.
　　23. Liu JY, Zhou ZG, Wu LZ, et al. (2012) Shear response of carbon fiber composite pyramidal truss structures after high-temperature exposure. Journal of Reinforced Plastics and Composites 31(18): 1216-1225.
　　24. Yu HJ, Wu LZ, Guo LC, et al. (2012) A domain-independent interaction integral for fracture analysis of nonhomogeneous piezoelectric materials. International Journal of Solids and Structures 49(23-24): 3301-3315.
　　25. Liu JY, Zhou ZG, Wu LZ, et al. (2012) A study on mechanical behavior of the carbon fiber composite sandwich panel with pyramidal truss cores at different temperatures. Science China-Physics Mechanics & Astronomy 55(11): 2135-2142.
　　26. Wu LZ, Pan SD (2012) Bounds on the overall properties of composites with ellipsoidal inclusions. Acta Mechanica Sinica 28(5): 1340-1355.
　　27. Lou J, Ma L, Wu LZ (2012) Free vibration analysis of simply supported sandwich beams with lattice truss core. Materials Science and Engineering B-Advanced Functional Solid-State Materials 177(19): SI: 1712-1716.
　　28. Zhou ZG, Tang YL, Wu LZ (2012) Non-local theory solution to two collinear limited-permeable mode-I cracks in a piezoelectric /piezomagnetic material plane. Science China-Physics Mechanics & Astronomy 55(7): 1272-1290.
　　29. Xiong J, Ma L, Vaziri A, Yang J, Wu L (2012) Mechanical behavior of carbon fiber composite lattice core sandwich panels fabricated by laser cutting. Acta Materialia 60(13-14): 5322-5334.
　　30. Xiong J, Ma L, Pan S, Wu L, et al. (2012) Shear and bending performance of carbon fiber composite sandwich panels with pyramidal truss cores. Acta Materialia 60(4): 1455-1466.
　　31. Liu J, Zhou ZG, Wu LZ, Ma L, Pan SD (2012) High temperature residual properties of carbon fiber composite sandwich panel with pyramidal truss cores. Applied Composite Materials, p 1-16.
　　32. Yin S, Wu LZ, Nutt S (2013) Stretch-bend-hybrid hierarchical composite pyramidal lattice cores. Composite Structures 98: 153-159.
　　33. Zhang GQ, Wang B, Ma L, Xiong J, Wu LZ (2013) Response of sandwich structures with pyramidal truss cores under the compression and impact loading. Composite Structures 100: 451-463.
　　34. He X, Wu LZ (2013) Design of two dimensional nonsingular internal-external cloaks with arbitrary cross-section. Science China-Physics Mechanics & Astronomy 56(7): 1373-1383.
　　35. He X, Wu LZ (2013) Design of two-dimensional open cloaks with finite material parameters for thermodynamics. Applied Physics Letters 102(21): 211912.
　　36. Yin S, Jacobsen AJ, Wu LZ, et al. (2013) Inertial stabilization of flexible polymer micro-lattice materials. Journal of Materials Science 48(19): 6558-6566.
　　37. Liu JY, Zhou ZG, Wu LZ, et al. (2013) High temperature residual properties of carbon fiber composite sandwich panel with pyramidal truss cores. Applied Composite Materials 20(4): 537-552.
　　38. Zhang GQ, Wang B, Ma L, Xiong J, Yang JS, Wu LZ (2013) The residual compressive strength of impact-damaged sandwich structures with pyramidal truss cores. Composite Structures 105: 188-198.
　　39. Liu JY, Zhou ZG, Wu LZ, et al. (2013) Mechanical behavior and failure mechanisms of carbon fiber composite pyramidal core sandwich panel after thermal exposure. Journal of Materials Science & Technology 29(9): 846-854.
　　40. He X, Wu LZ (2013) Thermal transparency with the concept of neutral inclusion. Physical Review E 88(3): 033201.
　　41. Wang B, Xiong J, Wang XJ, Ma L, Zhang GQ, Wu LZ, Feng JC (2013) Energy absorption efficiency of carbon fiber reinforced polymer laminates under high velocity impact. Materials & Design 50: 140-148.
　　42. Pan SD, Zhou ZG, Wu LZ (2013) Basic solutions of multiple parallel symmetric mode-III cracks in functionally graded piezoelectric/ piezomagnetic material plane. Applied Mathematics and Mechanics-English Edition 34(10): 1201-1224.
　　43. Yang JS, Xiong J, Ma L, Wang B, Zhang GQ, Wu LZ (2013) Vibration and damping characteristics of hybrid carbon fiber composite pyramidal truss sandwich panels with viscoelastic layers. Composite Structures 106: 570-580.
　　44. Lou J, Wang B, Ma L, Wu LZ (2013) Free vibration analysis of lattice sandwich beams under several typical boundary conditions. Acta Mechanica Solida Sinica 26(5): 458-467.
　　45. Tang YL, Zhou ZG, Wu LZ (2013) The basic solution of a 3-D rectangular permeable crack in a piezoelectric/piezomagnetic composite material. Acta Mech Solida Sin 26: 0894-9166.
　　46. Xiong J, Ghosh R, Ma L, Vaziri A, Wang YL, Wu LZ (2014) Sandwich-walled cylindrical shells with lightweight metallic lattice truss cores and carbon fiber-reinforced composite face sheets. Composites Part A-Applied Science and Manufacturing 56: 226-238.
　　47. Wang B, Zhang GQ, He QL, Ma L, Wu LZ, Feng JC (2014) Mechanical behavior of carbon fiber reinforced polymer composite sandwich panels with 2-D lattice truss cores. Materials & Design 55: 591-596.
　　48. Yu HJ, Wu LZ, Li H (2014) A domain-independent interaction integral for magneto-electro-elastic materials. International Journal of Solids and Structures 51(2): 336-351.
　　49. Xiong J, Ma L, Stocchi A, Yang JS, Wu LZ, Pan SD (2014) Bending response of carbon fiber composite sandwich beams with three dimensional honeycomb cores. Composite Structures 108: 234-242.
　　50. Zhang GQ, Wang B, Ma L, Wu LZ, Pan SD, Yang JS (2014) Energy absorption and low velocity impact response of polyurethane foam filled pyramidal lattice core sandwich panels. Composite Structures 108: 304-310.
　　51. Yin S, Wu LZ, Nutt SR (2014) Compressive efficiency of stretch- stretch-hybrid hierarchical composite lattice cores. Materials & Design 56: 731-739.
　　52. Liu JY, Zhu X, Zhou ZG, Wu LZ, Ma L (2014) Effects of thermal exposure on mechanical behavior of carbon fiber composite pyramidal truss core sandwich panel. Composites Part B-Engineering 60: 82-90.
　　53. Xiong J, Zhang M, Stocchi A, Hu H, Ma L, Wu LZ, Zhang Z (2014) Mechanical behaviors of carbon fiber composite sandwich columns with three dimensional honeycomb cores under in-plane compression.  Composites Part B-Engineering 60: 350-358.
　　54. Yin S, Wu LZ, Nutt S (2014) In-plane compression of hollow composite pyramidal lattice sandwich columns. Journal of Composite Materials 48(11): 1337-1346.
　　55. Wang B, Zhang GQ, Wang SX, Ma L, Wu LZ (2014) High velocity impact response of composite lattice core sandwich structures. Applied Composite Materials 21(2): 377-389.
　　56. Lou J, Wu LZ, Ma L, et al. (2014) Effects of local damage on vibration characteristics of composite pyramidal truss core sandwich structure. Composites Part B-Engineering 62: 73-87.
　　57. Yin S, Wu LZ, Yang JS, et al. (2014) Damping and low-velocity impact behavior of filled composite pyramidal lattice structures. Journal of Composite Materials 48(15): 1789-1800.
　　58. Liu JY, Zhu X, Li TY, Zhou ZG, Wu LZ, Ma L (2014) Experimental study on the low velocity impact responses of all-composite pyramidal truss core sandwich panel after high temperature exposure. Composite Structures 116: 670-681.
　　59. Yang JS, Xiong J, Ma L, Zhang GQ, Wang XT, Wu LZ (2014) Study on vibration damping of composite sandwich cylindrical shell with pyramidal truss-like cores. Composite Structures 117: 362-372.
　　60. Wang ZY, Ma L, Yu HJ, Wu LZ (2014) Dynamic stress intensity factors for homogeneous and non-homogeneous materials using the interaction integral method. Engineering Fracture Mechanics 128: 8-21.
　　61. He X, Wu LZ (2014) Illusion thermodynamics: A camouflage technique changing an object into another one with arbitrary cross section. Applied Physics Letters 105(22): 221904.
　　62. Xiong J, Ghosh R, Ma L, Ebrahimi H, Hamouda AMS, Vaziri A, Wu LZ (2014) Bending behavior of lightweight sandwich-walled shells with pyramidal truss cores. Composite Structures 116: 793-804.
　　63. Xiong J, Wang B, Ma L, Papadopoulos J, Vaziri A, Wu L (2014) Three-dimensional composite lattice structures fabricated by electrical discharge machining. Experimental Mechanics 54(3): 405-412.
　　64. Yu GC, Wu LZ, Ma L, et al. (2015) Low velocity impact of carbon fiber aluminum laminates. Composite Structures 119: 757-766.
　　65. Liu HT, Zhou ZG, Wu LZ (2015) Non-local theory solution to a 3-D rectangular crack in an infinite transversely isotropic elastic material. Meccanica 50(4): 1103-1120.
　　66. Liu HT, Zhou ZG, Wu LZ, et al. (2015) Non-local theory solution to a rectangular crack in a 3D infinite orthotropic elastic medium. International Journal of Solids and Structures 58: 207-219.
　　67. Wu LZ (2015) Cylindrical thermal cloak based on the path design of heat flux. Journal of Heat Transfer-Transactions of the ASME 137 (2): 021301.
　　68. Liu JY, Qiao WF, Liu JX,  Xie D, Zhou ZG, Ma L, Wu LZ (2015) The compressive responses of glass fiber composite pyramidal truss cores sandwich panel at different temperatures. Composites Part A-Applied Science and Manufacturing 73: 93-100.
　　69. Yang JS, Xiong J, Ma L, Feng LN, Wang SY, Wu LZ (2015) Modal response of all-composite corrugated sandwich cylindrical shells. Composites Science and Technology 115: 9-20.
　　70. Yu HJ, Sumigawa T, Wu LZ, et al. (2015) Generalized domain- independent interaction integral for solving the stress intensity factors of nonhomogeneous materials. International Journal of Solids and Structures 67-68: 151-168.
　　71. Wu LZ, Gao PL (2015) Manipulation of the propagation of out-of-plane shear waves. International Journal of Solids and Structures 69-70: 383-391.
　　72. Liu JY, Qiao WF, Liu JX, Xie D, Zhou ZG, Wu LZ, Ma L (2015) High temperature indentation behaviors of carbon fiber composite pyramidal truss structures. Composite Structures 131: 266-272.
　　73. Xiong J, Mines R, Ghosh R,  Vaziri A, Ma L,  Ohrndorf A, Christ HJ, Wu LZ (2015) Advanced micro-lattice materials. Advanced Engineering Materials 17(9): 1253-1264.
　　74. Liu HT, Zhou ZG, Wu LZ (2015) Basic solution of two 3D rectangular cracks in an orthotropic elastic media. ZAMM-ZEITSCHRIFT FUR ANGEWANDTE MATHEMATIK UND MECHANIK 95(11): 1215 -1229.
　　75. Yu GC, Wu LZ, Feng LJ (2015) Enhancing the thermal conductivity of carbon fiber reinforced polymer composite laminates by coating highly oriented graphite films. Materials & Design 88: 1063-1070.
　　76. Yang TZ, Bai X, Gao DL, Wu LZ, Li BW, Thong JTL, Qiu CW (2015) Invisible sensors: simultaneous sensing and camouflaging in multiphysical fields. Advanced Materials 27(47): 7752-7758.
　　77. Feng LJ, Wu LZ, Yu GC (2016) An Hourglass truss lattice structure and its mechanical performances. Materials & Design 99: 581-591.
　　78. Yu GC, Wu LZ, Feng LJ, Yang W (2016) Thermal and mechanical properties of carbon fiber polymer-matrix composites with a 3D thermal conductive pathway. Composite Structures 149: 213-219.
　　79. Yang JS, Ma L, Schmidt R, Qi G, Schroeder KU, Xiong J, Wu LZ (2016) Hybrid lightweight composite pyramidal truss sandwich panels with high damping and stiffness efficiency. Composite Structures 148: 85-96.
　　80. Yu GC, Feng LJ, Wu LZ (2016) Thermal and mechanical properties of a multifunctional composite square honeycomb sandwich structure. Materials & Design 102: 238-246.
　　81. Gao PL, Wu LZ (2016) Non-singular acoustic cloak derived by the ray tracing method with rotationally symmetric transformations. Proceedings of the Royal Society A-Mathematical Physical and Engineering Sciences 472(2186): 20150348n.
　　82. Wu QQ, Ma L, Wu LZ, Xiong J(2016) A novel strengthening method for carbon fiber composite lattice truss structures. Composite Structures 153: 585-592.
　　83. Li XD, Wu LZ, Ma L, Yan XQ (2016) Fabrication and mechanical properties of composite pyramidal truss core sandwich panels with novel reinforced frames. Journal of Reinforced Plastics and Composites 35(16): 1260-1274.
　　84. Yu HJ, Wang J, Shimada T, Wu HP, Wu LZ, Kuna M, Kitamura T (2016) An I-integral method for crack-tip intensity factor variation due to domain switching in ferroelectric single-crystals. Journal of the Mechanics and Physics of Solids 94: 207-229.
　　85. Jin Y, Jia XY, Wu QQ, Yu GC, Zhang XL, Chen S, Wu LZ (2022) Design of cylindrical honeycomb sandwich meta-structures for vibration suppression. Mechanical Systems and Signal Processing
　　86. Chen XJ,  Yu GC, Wang ZX , Feng LJ, Wu LZ(2021) Enhancing out-of-plane compressive performance of carbon fiber composite honeycombs. Composite Structures
　　87. Xiao ZQ, Gao PL, Wang DW, He X, Wu LZ (2021) Ventilated  metamaterials for broadband sound insulation and tunable transmission at low frequency. Extreme Mechanics Letters
　　88. Liu ZX, Zhao WK, Yu GC, Wu LZ (2021) Fabrication and mechanical behaviors of quartz fiber composite honeycomb with extremely low permittivity. Composite Structures
　　89. Li S, Yang JS, Rüdiger Schmidt, Wu LZ, Kai-Uwe Schroder.(2021) Compression and hysteresis responses of multilayer gradient composite lattice sandwich panels. Marine Structures.
　　90. Yang LH, Sui LH, Dong YL, Li XY, Zi F, Zhang ZX, Yang SJ, Yang JS, Wu LZ (2021) Quasi-static and dynamic behavior of sandwich panels with multilayer gradient lattice cores. Composite Structures
　　91. Yang LH, Sui L, Li XY, Dong YL, Zi F, Wu LZ (2021)Sandwich plates with gradient lattice cores subjected to air blast loadings, Mechanics of Advanced Materials and Structures, 28:13, 1355-1366
　　92. Yang LH, Han X, Feng LJ, Chen ZB, Yu GC, Qu J, Yang JS, Wu LZ (2020) Numerical investigations on blast resistance of sandwich panels with multilayered graded hourglass lattice cores. Journal of Sandwich Structures and Materials 22(7)：2139-2156
　　93. Yang LH, Chen ZB, Dong YL, Zi F, Yang JS, Wu LZ (2020): Ballistic performance of composite armor with dual layer piecewise ceramic tiles under sequential impact of two projectiles, Mechanics of Advanced Materials and Structures
　　94. Li S, Yang JS, Chen SY, Zhang WM, Rüdiger Schmidt, Kai-Uwe Schröder, Yang LH, Wu LZ  (2020): Modal response and vibration attenuation of carbon fiber composite sandwich cylindrical panels made of bi-directional corrugated strip cores,Mechanics of Advanced Materials and Structures
　　95. Yang JS, Liu ZD, Rüdiger Schmidt, Kai-Uwe Schröder, Ma L, Wu LZ.(2020) Vibration-based damage diagnosis of composite sandwich panels with bidirectional corrugated lattice cores. Composites Part A
　　96. Yang JS, Zhang WM, Yang F, Chen SY, Rüdiger Schmidte, Kai-Uwe Schröder, Ma L, Wu LZ (2020) Low velocity impact behavior of carbon fibre composite curved corrugated sandwich shells. Composite Structures
　　97. Yang JS, Chen SY, Li S, Pang YZ, Rüdiger Schmidt, Kai-Uwe Schröder , Qu J, Wu LZ (2020) Dynamic responses of hybrid lightweight composite sandwich panels with aluminium pyramidal truss cores. Journal of Sandwich Structures and Materials 0(0) 1–20
　　98. Li S, Yang JS, Wu LZ, Yu GC, Feng LJ (2019) Vibration behavior of metallic sandwich panels with Hourglass truss cores. Marine Structures. 63:84-98
　　99. Yang LH, Qu J, Yu GX, Yang JS, Wu LZ (2019) The effect of strain-rate sensitivity on dynamic response of impulsively loaded sandwich beam, Mechanics of Advanced Materials and Structures, 26:20, 1743-1749
　　100. Zhang XW，He X，Wu LZ（2019）Three-dimensional thermal illusion devices with arbitrary shape.Chinese Physics B 28(6)
　　101. 李爽, 杨金水, 吴林志, 于国财, 杨丽红, 曲嘉. 边界和杆件倾角对沙漏点阵结构振动特性的影响. 哈尔滨工程大学学报. 2019, 40(05): 878-885
　　102. Wu QQ, Vaziri A, Asl ME, Ghosh R, Gao Y, Wei XY(2019) Lattice materials with pyramidal hierarchy: Systematic analysis and three dimensional failure mechanism maps. Journal of the Mechanics and Physics of Solids. 125:112-44
　　103. Tan XJ, Chen S, Wang B, Zhu SW, Wu LZ, Sun YG (2019) Design, fabrication, and characterization of multistable mechanical metamaterials for trapping energy. Extreme Mechanics Letters. 28:8-21
　　104. Li XD, Wu LZ, Ma L, Yan XQ (2019) Compression and shear response of carbon fiber composite sandwich panels with pyramidal truss cores after thermal exposure. Mechanics of Advanced Materials and Structures. 26:866-77
　　105. Hu B, Wu LZ, Xiong J, Ma L, Yang W, Jin Y (2019) Mechanical properties of a node-interlocking pyramidal welded tube lattice sandwich structure. Mechanics of Materials. 129:290-305
　　106. Gao PL, Climente A, Sanchez-Dehesa J, Wu LZ(2019) Single-phase metamaterial plates for broadband vibration suppression at low frequencies. Journal of Sound and Vibration 444:108-26
　　107. Feng LJ, Wei GT, Yu GC, Wu LZ(2019) Underwater blast behaviors of enhanced lattice truss sandwich panels. International Journal of Mechanical Sciences. 150:238-46
　　108. Du YT, Song CP, Xiong J, Wu LZ(2019) Fabrication and mechanical behaviors of carbon fiber reinforced composite foldcore based on curved-crease origami. Composites Science and Technology. 174:94-105

　　2017年获国家自然科学二等奖一项，第一完成人。（先进梯度功能材料的断裂力学研究，吴林志、周振功、果立成、马力）
　　2016年获黑龙江省科学技术奖自然科学一等奖一项，第一完成人。（超轻复合材料夹芯结构及其力学性能，吴林志、马力、熊健、王兵、泮世东）
　　2006年获教育部高等学校科学技术奖自然科学奖一等奖（多功能复合材料及结构的断裂行为研究，吴林志、马力、果立成、陈建、周振功）
　　1998年获教育部科技进步奖一等奖（含夹杂非均匀介质的理论研究，杜善义、王彪、吴林志、梁军、李文方）

　　2017 National Natural Science Second Prize, the first finisher
　　2016 Heilongjiang Province Science and Technology Award Natural Science First Prize, the first accomplisher  
　　2006 The first prize of Natural Science Award of Ministry of Education
　　1998 First prize of Science and Technology Progress Award of Ministry of Education