科研队伍
  • 姓名: 王超
  • 性别: 男
  • 职称: 副高级
  • 学历: 博士
  • 电话: 010-82543525
  • 传真: 010-82543977
  • 电子邮件: wangchao@lnm.imech.ac.cn
  • 通讯地址 北京市海淀区北四环西路15号

    简历:

  • 1999.9-2003.7 西南交通大学  获机械工程学士学位

    2005.9-2008.7 中国矿业大学(北京) 获工程力学硕士学位

    2008.9-2012.7 中国科学院力学研究所 获固体力学博士学位

    2012.7-2014.7 清华大学 航天航空学院 CNMM 博士后研究

    2014.7-2017.10 中科院力学所 非线性力学国家重点实验室 助理研究员

    2017.10-现在 中科院力学所 非线性力学国家重点实验室 副研究员

    研究领域:

  • 1. 纳米多孔材料

     研究由石墨烯、碳纳米管等典型纳米材料组成的宏观多孔材料的力学、物理性能,推动新型纳米多孔材料的发展。

    2. 3D打印人造心脏

     利用3D打印技术、有限元模拟等手段研究与心脏相关的科学问题,为解决心脏方面的疾病提供理论依据。

     

    指导研究生:杨田(硕博连读生,2016级)、胡天雄(硕士生,2019级)、Bilal Jadoon(博士生,2017级,与北京理工联合培养)

     

    社会任职:

    期刊审稿人:Carbon、ACS Applied Materials & Interfaces、Nanotechnology、Scientific Reports、Materials Research Express、哈尔滨工业大学学报

     

    招生情况:每年招收一名具有力学、物理、材料背景的研究生

     

    社会任职:

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    获奖及荣誉:

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    代表论著:

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    (一)期刊论文:#共同第一作者 *通讯作者

    在ACS Nano、Small、Carbon、JPCC等国际主流期刊发表论文20多篇。

      

    [23] Shuai Wang, Zhilong Peng, Chao Wang*, Shaohua Chen*. Influencing Factors of Droplet Aggregation on Hierarchical Wedge-Shaped Functional Surface. Under Review. 

    [22] Shuai Wang, Chao Wang*, Zhilong Peng, Shaohua Chen*. Spontaneous Dewetting Transition of Nanodroplets on Nanopillared Surface. Under Review. 

    [21] Tian Yang, Chao Wang*, Zuobing Wu*. Crosslink-tuned Large-Deformation Behavior and Fracture Mode in Buckypapers. Carbon. 2020, 159: 412-421; 

    [20] Muhammad Bilal Khan, Shuai Wang, Chao Wang* and Shaohua Chen*. Rotation of Nanoflake Driven by Strain Gradient Fields in Locally-Indented Graphene. Nanotechnology. 2020, 21(1):015303. 

    [19] Chao Wang, Cun Zhang, Shaohua Chen. The Micro-Mechanism and the Influencing Factors of Graphene Foam Elasticity. Carbon. 2019;148:267-276.

    [18] Shuai Wang, Chao Wang*, Zhilong Peng, Shaohua Chen*. Moving Behavior of Nanodroplets on Wedge-Shaped Functional Surfaces. The Journal of Physical Chemistry C. 2019; 123(3):1798-1805.

    [17] Shuai Wang, Chao Wang, Zhilong Peng, Shaohua Chen. A new technique for nanoparticle transport and its application in a novel nano-sieve. Scientific Reports. 2018; 8(1):1-10.

    [16] Douxing Pan, Chao Wang, Xiaojie Wang. Graphene Foam: Hole-Flake Network for Uniaxial Supercompression and Recovery Behavior. ACS Nano. 2018; 12(11):11491-11502.

    [15] Feng Liu*, Chao Wang*, Qiheng Tang. Conductivity Maximum in 3D Graphene Foams. Small. 2018;1801458:1-10.

    [14] Junjun Shang, Qingsheng Yang*, Xia Liu*, Chao Wang*.Compressive Deformation Mechanism of Honeycomb-like Graphene Aerogels. Carbon. 2018; 134:398-341.

    [13] Chao Wang, Douxing Pan, Shaohua Chen. Energy Dissipative Mechanism of Graphene Foam Materials. Carbon. 2018;132:641-650.

    [12] Douxing Pan#, Chao Wang#, Tzu-Chiang Wang,Yugui Yao.Graphene Foam:Uniaxial Tension Behavior and Fracture Mode Based on a Mesoscopic Model. ACS Nano. 2017;11(9):8988-8997.

    [11] Douxing Pan, Tzu-Chiang Wang, Chao Wang, Yugui Yao. Self-assembled chiral phosphorus nanotubes from phosphorene: A molecular dynamics study. RSC Advances. 2017; 7(40):24647-24651.

    [10] Chao Wang, Cun Zhang, Shaohua Chen. The microscopic deformation mechanism of 3D graphene foam materials under uniaxial compression. Carbon. 2016; 109:666-672.

    [9] Chao Wang, Shaohua Chen.Viscoelastic properties of randomly entangled carbon nanotube networks under cyclic tension loading. Computational Materials science. 2016; 119:46-51.

    [8] Chao Wang, Shaohua Chen. Motion driven by strain gradient fields. Scientific Reports. 2015; 5:13675.

    [7] Chao Wang, Wang LF, Xu ZP. Mechanics of networked materials with dynamical crosslinks. Comptes Rendus Mecanique. 2014; 342(5):264-72.

    [6] Chao Wang, Wang LF, Xu ZP. Enhanced mechanical properties of carbon nanotube networks by mobile and discrete binders. Carbon. 2013; 64(2013):237-44. 

    [5] Chao Wang, Xie B, Liu YL, Xu ZP. Mechanotunable microstructures of carbon nanotube Networks. ACS Macro Letters. 2012; 1(10):1176-9.

    [4] Chao Wang, Chen SH. Application of the complex network method in solid-state sintering. Computational Materials Science. 2013; 69:14-21. 

    [3] Chao Wang, Chen SH. The influence of agglomerates on the densification and microstructural evolution in sintering of a multi-particle system. Science China Physics, Mechanics and Astronomy. 2012; 55(6):1051-8.

    [2] Chao Wang, Chen SH. The effect of agglomerate on micro-structural evolution in solid-state sintering. Acta Mechanica Sinica. 2012; 28(5):1323-30.

    [1] Chao Wang, Chen SH. Factors influencing particle agglomeration during solid-state sintering. Acta Mechanica Sinica. 2012; 28(3):711-9.

      

    (二)会议论文/摘要: 

    [4] 王超,陈少华. 石墨烯泡沫材料拉压弹性机理研究. 2018全国固体力学大会. 哈尔滨. 2018.11.23-26

    [3] 王超,陈少华. 惰性夹杂颗粒对固相烧结的影响. 第15届北方七省市区力学会议. 8/2014

    [2] 王超,陈少华. 微颗粒烧结过程中颗粒聚团的影响因素. 中国力学大会. 7/2011

    [1] 王超,陈少华. 固相烧结中颗粒团的影响(摘要). 北京力学会第十七届年会. 1/2011

     

     

    承担科研项目情况:

  • 国家自然科学基金面上项目 2020-2023 石墨烯泡沫材料微观变形机制及其力电性能调控机理的数值模拟研究 

    国家自然科学基金青年基金 2017-2019 CNT网络/Polymer复合材料力学性能的多尺度数值模拟研究

    博士后基金一等资助 2013年 两类交联对碳纳米管网络材料力学性能的调控机理研究