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张阿漫

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张阿漫

中文名张阿漫

职业教授、博士生导师

主要成就全国创新争先奖国家技术发明二等奖1项国家科技进步二等奖1项科学探索奖

毕业院校大连理工大学、哈尔滨工程大学

国籍中国

目录导航

人物经历

2003年本科毕业于大连理工大学船舶与海洋工程专业。

2007年在哈尔滨工程大学船舶与海洋工程专业取得博士学位。

2011年赴英国伦敦大学学院(UCL)做访问学者。

主要成就

张老师在办公室主要研究方向：爆炸冲击动力学、流固耦合动力学、气泡动力学^[1]，承担国家重点研发计划重点专项、国家自然科学基金、国防基础科研等科研项目共40余项。针对近场爆炸与结构毁伤及防护难题，建立了近场水下爆炸等大尺度气泡动力学理论模型与方法，探明了近边界气泡系列动力学行为与载荷形成机理；提出了水下爆炸全耦合强非线性瞬态流固耦合模型与计算方法，解决了近场接触爆炸领域的多项关键理论和瓶颈技术问题，揭示了水下爆炸对舰船结构毁伤与防护力学机制，形成了近场爆炸与结构毁伤及防护新技术。研究成果已应用于我国10余型新研大型舰船的抗爆抗冲击评估与设计之中，以及水中兵器水下爆炸毁伤威力评估、跨介质航行器水动力论证与设计、航天飞行器爆炸分离评估与设计、深海勘探高压气枪阵列设计与开发等领域之中，为提高我国航母、核潜艇、战略潜射导弹、中国载人空间站等多个国家战略型号的抗冲击能力提供了基础理论和技术支撑^[1]。获得了全国创新争先奖（2020），国家技术发明二等奖1项（2018），国家科技进步二等奖1项（2013），国家级教学成果二等奖1项（2018），省部级一等奖3项。在《Journal of Fluid Mechanics》、《Physical Review Fluids》、《Physics of Fluids》、《Journal of Computational Physics》、《CMAME》等权威期刊上发表学术论文100余篇，被引4000余次，ESI高被引论文9篇。获得授权发明专利15项，软件著作权38项，出版书籍3部，海军标准1部。获得了首届科学探索奖（2019）、中国高被引学者（2019）、中青年科技创新领军人才（2016）等学术荣誉，担任中国造船工程学会船舶力学学术委员会副主任，军委科技委基础研究先进HS与评估专业组成员，SCI期刊《Computer Modeling in Engineering & Sciences》副主编，以及《Applied Ocean Research》、《Journal of Hydrodynamics》、《Theoretical & Applied Mechanics Letters》等多个学术期刊的编委^[1]。获得了国家杰出青年科学基金、国家“万人计划”科技创新领军人才、国防科技卓越青年科学基金等学术荣誉^[1]。

科研项目

1) 2019.11-2024.12，国家杰出青年科学基金项目，水下爆炸与舰船毁伤，主持^[1]。

2) 2018.11-2022.12，GF科技卓越青年科学基金项目，***水下近场爆炸对**结构毁伤机理研究，主持。

3) 2018.09-2021.12，国家重点研发计划重点专项，适用于主动源地震的船载高压气枪研制，主持。

4) 2018.04-2020.12，国家高层次人才特殊支持计划，主持。

5) 2018.01-2022.12，基础加强计划重点基础研究项目课题， **跨介质流固耦合与瞬态冲击机理研究，主持。

6) 2018.01-2020.12，GF基础科研，波浪条件下水下爆炸冲击波和气泡对**结构的毁伤特性研究，主持。

7) 2017.01-2020.12，GF科技创新特区，水下高效**方法研究，主持。

8) 2017.01-2020.12，国家自然科学基金，海底资源探测气枪气泡动力学特性研究，主持。

9) 2015.01-2018.12，GF973专题，瞬态外压载荷时间特性对结构动力失效的影响，主持。

10) 2015.01-2018.12，国家自然科学基金(重点项目)，考虑船体结构的水下爆炸流固耦合研究，参加。

11) 2014.01-2017.12，国家自然科学基金，近场爆炸气泡与不完整边界耦合效应研究，主持。

12) 2013.01-2015.12，国家自然科学基金，水下爆炸与舰船毁伤基础力学问题，主持。

13) 2013.01-2015.12，教育部高等学校博士学科点专项科研基金，气泡压力作用下结构动力学研究，主持。

14) 2013.01-2014.12，GF基础科研，水下爆炸气泡射流对**结构毁伤与失效机理，主持。

15) 2012.01-2014.12，GF预研，水下远场非接触爆炸作用下***结构冲击响应特性预报方法标准化，主持。

16) 2011.01-2014.12，GF973专题，水下爆炸气泡作用下壳体结构的总体冲击毁伤力学行为，主持。

17) 2011.01-2013.12，教育部新世纪优秀人才支持计划，舰船总体与局部结构在气泡作用下损伤研究，主持。

18) 2011.01-2012.12，GF基础科研， ***穿越水面过程载荷特性基础力学研究，参加。

19) 2010.01-2013.12，国家自然科学基金(重点项目)，水下爆炸对舰船结构毁伤机理与规律，参加。

20) 2010.01-2013.12，第十二届霍英东教育基金，水下爆炸气泡与舰船结构耦合动态特性研究，主持。

21) 2010.01-2012.12，国家自然科学基金，水下爆炸气泡与弹性边界相互作用的值模拟，主持。

22) 2009.01-2011.12，国家自然科学基金，近自由面水下爆炸气泡与水冢现象相互作用的机理研究，主持。

23) 2008.01-2010.12，科技部国际合作项目，中俄船舶的抗冲击防护结构研究，参加。

学术论文

[1] P. Cui, A.M. Zhang, S.P. Wang, Y.L. Liu. Experimental study on interaction, shock wave emission and ice breaking of two collapsing bubbles. Journal of Fluid Mechanics, 2020, 897: A25^[1].

[2] L. Ge, A.M. Zhang, S.P. Wang. Investigation of underwater explosion near composite structures using a combined RKDG-FEM approach. Journal of Computational Physics, 2020, 404:109113.

[3] Y.X. Peng, A.M. Zhang, F.R. Ming. A 3D meshfree crack propagation algorithm for the dynamic fracture in arbitrary curved shell. Computer Methods in Applied Mechanics and Engineering, 2020, 367:113139.

[4] M.K. Li, A.M. Zhang, F.R. Ming, P.N. Sun, Y.X. Peng. An axisymmetric multiphase SPH model for the simulation of rising bubble. Computer Methods in Applied Mechanics and Engineering, 2020, 366:113039.

[5] Z.F. Meng, P.P. Wang, A.M. Zhang, F.R. Ming, P.N. Sun. A multiphase SPH model based on Roe’s approximate Riemann solver for hydraulic flows with complex interface. Computer Methods in Applied Mechanics and Engineering. 2020, 365(15): 112999.

[6] N.N. Liu, A.M. Zhang, Y.L. Liu, T. Li. Numerical analysis of the interaction of two underwater explosion bubbles using the compressible Eulerian finite-element method. Physics of Fluids, 2020, 32 (4): 046107.

[7] S. Li, D. van der Meer, A.M. Zhang, A. Prosperetti, D. Lohse. Modelling large scale airgun-bubble dynamics with highly non-spherical features. International Journal of Multiphase Flow, 2020, 122: 103143.

[8] P.P. Wang, Z.F. Meng, A.M. Zhang, F.R. Ming, P.N. Sun. Improved particle shifting technology and optimized free-surface detection method for free-surface flows in smoothed particle hydrodynamics.Computer Methods in Applied Mechanics and Engineering, 2019, 357:112580.

[9] C. Li, A.M. Zhang, S.P. Wang, P. Cui. Effects of nanostructured substrates on the dynamic behavior of nanobubbles. Physical Review Fluids, 2019, 4 (10): 103603.

[10] S.M. Li, A.M. Zhang, Q.X. Wang, S. Zhang. The jet characteristics of bubbles near mixed boundaries. Physics of Fluids, 2019, 31 (10): 107105.

[11] Y.L. Liu, A.M. Zhang, Z.L. Tian, S.P. Wang. Dynamical behavior of an oscillating bubble initially between two liquids. Physics of Fluids, 2019, 31 (9): 092111.

[12] G.Q. Chen, X. Huang, A.M. Zhang, S.P. Wang, T. Li. Three-dimensional simulation of a rising bubble in the presence of spherical obstacles by the immersed boundary–lattice Boltzmann method. Physics of Fluids, 2019, 31(9): 097104.

[13] S. Li, A.M. Zhang, R. Han, Q. Ma. 3D full coupling model for strong interaction between a pulsating bubble and a movable sphere. Journal of Computational Physics, 2019, 392: 713-731.

[14] G.Q. Chen, X. Huang, A.M. Zhang, S.P. Wang. Simulation of three-dimensional bubble formation and interaction using the high-density-ratio lattice Boltzmann method. Physics of Fluids, 2019, 31(2): 027102.

[15] P.P. Wang, A.M. Zhang, F.R. Ming, P.N. Sun, H. Cheng. A novel non-reflecting boundary condition for fluid dynamics solved by smoothed particle hydrodynamics. Journal of Fluid Mechanics, 2019, 860:81-114.

[16] Y.X. Peng, A.M. Zhang, F.R. Ming, S.F. Li. A beam formulation based on RKPM for the dynamic analysis of stiffened shell structures. Computational Mechanics, 2019, 63(1):35-48.

[17] S. Li, A.M. Zhang, R. Han. Counter-jet formation of an expanding bubble near a curved elastic boundary. Physics of Fluids, 2018, 30(12):121703.

[18] C. Li, S.P. Wang, A.M. Zhang, Y. Liu. Dynamic behavior of two neighboring nanobubbles induced by various gas-liquid-solid interactions. Physical Review Fluids, 2018, 3(12):123604.

[19] P. Cui, A.M. Zhang, S.P. Wang, B.C. Khoo. Ice breaking by a collapsing bubble. Journal of Fluid Mechanics, 2018, 841:287-309.

[20] S. Li, A.M. Zhang, S. Wang, R. Han. Transient interaction between a particle and an attached bubble with an application to cavitation in silt-laden flow. Physics of Fluids, 2018, 30 (8):082111.

[21] Y.X. Peng, A.M. Zhang, F.R. Ming. A thick shell model based on reproducing kernel particle method and its application in geometrically nonlinear analysis. Computational Mechanics, 2018, 62(2): 309-321.

[22] H. Cheng, A.M. Zhang, F.R. Ming. Study on coupled dynamics of ship and flooding water based on experimental and SPH methods. Physics of Fluids, 2017, 29 (10):107101.

[23] S. Zhang, A.M. Zhang, S.P. Wang, J. Cui. Dynamic characteristics of large scale spark bubbles close to different boundaries. Physics of Fluids, 2017, 29 (9):092107.

[24] S. Li, A.M. Zhang, R. Han, Y.Q. Liu. Experimental and numerical study on bubble-sphere interaction near a rigid wall. Physics of Fluids, 2017, 29 (9):092102.

[25] A.M. Zhang, W.B. Wu, Y.L. Liu, Q.X. Wang. Nonlinear interaction between underwater explosion bubble and structure based on fully coupled model. Physics of Fluids, 2017, 29 (6):082111.

[26] P. Cui, A. M. Zhang, S. P. Wang. Small-charge underwater explosion bubble experiments under various boundary conditions. Physics of Fluids, 2016, 28:117103.

[27] R. Han, S. Li, A. M. Zhang, Q. X. Wang. Modelling for three dimensional coalescence of two bubbles. Physics of Fluids, 2016, 28: 062104.

[28] Y. L. Liu, S. P. Wang, and A. M. Zhang. Interaction between bubble and air-backed plate with circular hole. Physics of Fluids, 2016, 28: 062105.

[29] A.M. Zhang, P. Cui, J. Cui, Q.X.Wang. Experimental study on bubble dynamics subject to buoyancy. Journal of Fluid Mechanics, 2015, 776: 137-160.

[30] A.M. Zhang, Y.L. Liu. Improved three-dimensional bubble dynamics model based on boundary element method. Journal of Computational Physics, 2015, 294: 208-223.

[31] A.M. Zhang, S. Li, J. Cui. Study on splitting of a toroidal bubble near a rigid boundary. Physics of Fluids, 2015, 27: 062102.

[32] A.M. Zhang, B.Y. Ni. Three-dimensional boundary integral simulations of motion and deformation of a bubble with viscous effects. Computers & Fluids, 2014, 92(20):22-33.