(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30多篇。
-- 2023 --
[35] Tian Yang, Tianxiong Hu, Chao Wang* and Zuobing Wu*. Micro-mechanism of Plasticity of Graphene Foams. 2023, In Preparation;
[34] Shenggui Liu, Mindong Lyu, Cheng Yang and Chao Wang*. Viscoelastic Properties of Graphene Foams using Dynamic Mechanical Analysis and Coarse-Grained Molecular Dynamics Simulations. 2023, In Preparation;
[33] Shuai Wang, Tian Yang, Chao Wang*, Lihong Liang*. The Mechanical Response and Microscopic Deformation Mechanism of Graphene Foams Tuned by Long Carbon Nanotubes and Short Crosslinkers. Physical Chemistry Chemical Physics, 2023, In Press;
-- 2022 --
[32] Tianxiong Hu, Guian Qian, Xianqian Wu, Chao Wang*. Mechanical Behavior and Micro-Mechanism of Carbon Nanotube Networks under Friction. Carbon, 2022, 200(2022), 108-115;
[31] Muhammad Bilal Khan, Chao Wang*, Shuai Wang and Shaohua Chen*. Mechanical Properties and Micro-Mechanisms of Nanoparticles-Contained Graphene Foams under Uniaxial Tension. Computational Materials Science. 2022, 206(11):111277;
[30] Yue Wu, Chao Wang* and Tian Yang. Aggregation of Nanoparticles and Their Effect on Mechanical Properties of Carbon Nanotube Networks. Computational Materials Science. 2022, 202:110970;
-- 2021 --
[29] Shenggui Liu, Mindong Lyu and Chao Wang*. Mechanical Properties and Deformation Mechanisms of Graphene Foams with Bi-Modal Sheet Thickness by Coarse-Grained Molecular Dynamics Simulations. Materials. 2021, 14(19):5622;
[28] Tian Yang, Chao Wang* and Zuobing Wu*. Strain Hardening in Graphene Foams under Shear. ACS Omega. 2021, 6(35):22780-22790;
[27] Shuai Wang, Chao Wang*, Muhammad Bilal Khan and Shaohua Chen*. Microscopic Deformation Mechanism and Main Influencing Factors of Carbon Nanotube Coated Graphene Foams under Uniaxial Compression. Nanotechnology. 2021, 32(34):345704;
[26] Yifan Zhao, Yushun Zhao, Fan Wu, Yue Zhao, Yaming Wang, Chao Sui, Xiaodong He, Chao Wang*, Huifeng Tan* and Chao Wang*. The Mechanical Behavior and Collapse of Graphene-Assembled Hollow Nanospheres under Compression. Carbon. 2021, 173, 600-608;
[25] Kailu Xiao, Xudong Lei, Yuyu Chen, Qi An, Dongmei Hu, Chao Wang*, Xianqian Wu* and Chengguang Huang. Extraordinary Impact Resistance of Carbon Nanotube Film with Crosslinks under Micro-Ballistic Impact. Carbon. 2021, 175, 478-489;
[24] Muhammad Bilal Khan, Chao Wang*, Shuai Wang, Daining Fang and Shaohua Chen*. The Mechanical Property and Microscopic Deformation Mechanism of Nanoparticle-Contained Graphene Foam Materials under Uniaxial Compression. Nanotechnology. 2021, 32(11):115701;
-- 2020 --
[23] Shuai Wang, Zhilong Peng, Jianjun Li, Yazheng Yang,Chao Wang*, Shaohua Chen*. Influencing Factors of Droplet Aggregation on Hierarchical Wedge-Shaped Functional Surface. Computational Materials Science. 2020; 175:109616;
[22] Shuai Wang, Chao Wang*, Zhilong Peng, Shaohua Chen*. Spontaneous Dewetting Transition of Nanodroplets on Nanopillared Surface. Nanotechnology. 2020, 31(22):225502;
[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.
-- 2019 --
[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.
-- 2018 --
[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.
-- 2017 --
[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.
-- 2016 --
[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.
-- 2015 --
[8] Chao Wang, Shaohua Chen. Motion Driven by Strain Gradient Fields. Scientific Reports. 2015; 5:13675.
-- 2014 --
[7] Chao Wang, Wang LF, Xu ZP. Mechanics of Networked Materials with Dynamical Crosslinks. Comptes Rendus Mecanique. 2014; 342(5):264-72.
-- 2013 --
[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, Chen SH. Application of the Complex Network Method in Solid-State Sintering. Computational Materials Science. 2013; 69:14-21.
-- 2012 --
[4] Chao Wang, Xie B, Liu YL, Xu ZP. Mechanotunable Microstructures of Carbon Nanotube Networks. ACS Macro Letters. 2012; 1(10):1176-9.
[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)专利和软件注册权
[1] 王超,考虑力电耦合机理的全心脏数值模拟软件V1.0,登记号:2022SR1033830,2022.
(三)参加会议
[7] 王超. 石墨烯泡沫材料的研究进展和研究计划. 第一届CEL研究组毕业生研讨会. 北京. 2020.12.26
[6] 王超. 石墨烯泡沫材料力电性能的微观机理研究. 固体力学青年学术沙龙. 2020.8.5
[5] 王超. 石墨烯泡沫材料弹性机理研究. 2019年中国力学大会. 杭州. 2019.8.25-28
[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