曹国鑫，教授

同济大学航空航天与力学学院，
应用力学研究所
东大楼321室，彰武路100号
邮编：200092
email: caogx@tongji.edu.cn。
教育背景:
2000.8-2004.12,美国Clemson大学,材料科学与工程, 获得博士学位
1996.9-2000.3,北京航空航天大学，材料科学, 获得博士学位
1993.9-1996.7，内蒙古工业大学，固体力学，获得硕士士学位
1989.9-1993.7，大连理工大学，化工机械，获得学士学位
工作经历:
从2017年10月至今：教授，同济大学航空航天与力学学院
2010年9月—2017年9月：特聘研究员，北京大学工学院力学与科学技术系
2008年8月—2010年8月：研究助理教授，美国Nebraska-Lincoln大学工程力学系
2005年1月—2008年5月：博士后在美国Columbia大学纳米力学中心，土木工程力学系
2000年9月—2004年11月：研究助理在美国Clemson大学机械工程系
主要研究领域:
微纳米力学，物理力学和复杂材料力学行为多尺度计算模拟，新型纳米复合吸能材料等。长期在微纳米测试分析力学领域从事相关研究工作，以跨尺度理论计算为主要手段、辅以实验测试的方法，取得一些具有鲜明特色的成果，主要体现在建立低维材料与结构的基本力学模型和测试分析方法。
主要学术贡献如下：首先，突破传统纳米压痕技术的应用局限，使带基底二维材料、石墨烯电子皮肤力学性能测试成为可能；从模型和实验设置两方面完善二维材料压痕测试分析方法，实现其弹性模量的准确测量；并阐明经典力学模型对二维材料的适用性，为基于低维材料的电子皮肤类柔性传感器的设计和工程应用提供理论基础。其次，搭建一维液固复合模型，提出纳米尺度下液体基本力学行为的计算模拟新方法，将准确计算纳米流体表面张力、液固接触角、Young-Laplace方程变成可能；建立一种冲击能吸收新机制和模型，使高吸能密度、低响应时间、可重复使用变成可能，具有显著工程应用价值。
已发表SCI论文82篇，总引用超过3100次，H因子32（Google Scholar数据）。发表相关研究领域综述文章5篇，其中《力学进展》2篇，《Progress in Material Science》《中国科学》和《Polymers》各1篇。另外，多次受邀在国内外学术会议、研究机构作学术邀请报告。
代表性论文：
1.Guoxin Cao*and HuaJian Gao*.Mechanical properties characterization of two- dimensional materials via nanoindentation experiments. Progress in Materials Science, 103: 558-595 (2019). (SCI, IF = 23.75)
2.Tianxiao Niu, Guoxin Cao*，and Chunyang Xiong. Indentation Behavior of the Stiffest Membrane Mounted on a Very Compliant Substrate: Graphene on PDMS, International Journal of Solids and Structures, 132, 1-8 (2018). (SCI, IF = 2.2)
3.Liusi Yang, Tianxiao Niu, Hui Zhang, Wenjing Xu, Mingchu Zou, Lu Xu, Guoxin Cao*and Anyuan Cao*. Self-assembly of suspended graphene wrinkles with high pre-tension and elastic property. 2D Materials, 4, 041001 (2017). (SCI, IF = 6.9)
4.Guoxin Cao*. Nanofluidic Energy Absorption System: A review. Advances in Mechanics, 47: 201706, (2017).
5.Tianxiao Niu, Guoxin Cao*，and Chunyang Xiong*. Fracture behavior of graphene mounted on stretchable substrate, Carbon,109, 852-859 (2016). (SCI, IF = 6.2)
6.Hailong Liu and Guoxin Cao*, Effectiveness of the Yang-Laplace equation at nanoscale,Scientific Reports2016, 6, 23936. (SCI, IF = 5.8)
7.Guoxin Cao*. Atomistic Studies of Mechanical Properties of Graphene, Polymers, 6(9), 2404-2432(2014). (SCI, IF = 3.7)
获得的主要成就及奖励（AWARDS）:
l2018英国物理学会（IOP publishing）中国作者高引用论文奖
l2018同济大学荣泰奖教金
l2017英国物理学会（IOP publishing）最佳论文评审人奖
l北京大学第11届青年教师教学基本功比赛二等奖；
l2012年度北京大学优秀班主任三等奖；
lThe 2010 Layman Award of University of Nebraska-Lincoln；
l获得Columbia大学2008年BWF (Burroughs Wellcome Fund) Career Awards at the Scientific Interface 提名（总共两人获提名）。
专业活动:
2018年上海力学协会会员
2014年北京大学工学院第一届博士生论坛组委会主任委员
2013年北京振动工程学会理事
2012年力学全国博士生学术论坛组织委员会委员
2012年3月PKU-YNU Joint Workshop成员
2011 年全国塑性力学会议组织委员会委员
2013年秋季主持北京大学力学系与湍流国家重点实验室学术邀请报告
2010年秋季主持北京大学力学系与湍流国家重点实验室学术邀请报告
美国机械工程协会成员（ASME member 2005-2010）
美国材料协会成员(MRS member 2009-2010),
l专业期刊审稿人(Journal reviewer)
Physical Review Letters
Journal of American Society of Chemistry

Advanced Materials，
ACSNano，

Computational Material Science
Physical Review B

International Journal of Solid Structures
Applied surface science

Physical Review E
Mechanics Research Communications

Journal of Nanoengineering and Nanosystems
Journal of Biomechanics

Nanotechnology
Composites Part A

Journal of physical chemistry
Journal of chemical physics

Carbon
Theoretical & Applied Mechanics

Journal of Nanomechanics and Micromechanics
Journal of Composite Materials

Chemical Engineering Science
Part B: Journal of Engineering Manufacture

Nanoletters
Composites Part B

Scientific Reports
Journal of the Mechanical Behavior of Biomedical Materials,

Nanoscale;
Tissue Engineering

l博士论文评阅人
l基金项目评阅人
l邀请报告(Invited Presentations):
1.2019年4月24日，东华大学纺织科技创新中心邀请报告，Mechanical properties characterization of two-dimensional materials via nanoindentation experiments。
2.2019年4月12日-14日，第四届低维材料力学青年研讨会邀请报告，“二维材料力学行为的压痕测试”，江南大学，无锡。
3.2019年3月12日，北京理工大学爆炸科学与技术国家重点实验室邀请报告，Mechanical properties characterization of two-dimensional materials via nanoindentation experiments。
4.2018年11月30日，浙江大学固体力学所邀请报告，Discussion of Mechanics of Traumatic Brain Injury。
5.2018年9月21-23日，第十五届全国物理力学学术会议，G 分会：第三届低维材料力学青年研讨会邀请报告，“带基底二维材料的压痕响应”，合肥。
6.2018年4月19日，西安交通大学机械结构强度与振动国家重点实验室邀请报告“Mechanical properties characterization of two-dimensional materials via nanoindentation experiments”。
7.2017年3月10日，北航大学汽车工程系邀请报告，“纳米流控能量吸收系统”。
8.2016年9月27-29日，第十四届全国物理力学学术会议，多尺度物理力学分会邀请报告“Graphene/PDMS纳米复合结构的纳米压痕响应”。
9.2016/07/05, Polymer and Composite Engineering Group (PaCE), University of Vienna, “Mechanical response of graphene/PDMS nanocomposite under nanoindentation”;
10.2016/04/15, Department of Engineering Mechanics, Tsinghua University, Beijing China, “Wetting properties of liquids at nano- environments”;
11.2016/04/15, Department of Mechanics and Engineering Science, Peking University, Beijing China, “Multiscale simulation of mechanical behavior of low-dimensional materials”;
12.2015/09/07, Beijing Institute of Applied Physics and Computational Mathematics, Beijing China, “working mechanism of nanoporous energy absorption system under high speed loading”;
13.2015/09/19, International Computational Mechanics Workshop, Peking University, Beijing China, “Free-standing indentation response of 2D materials”;
14.2015/07/13, 2015 International Conference of Computational Mechanics (ICCM), Auckland, Newzeland, Symposium Keynote talk “FEM study of the indentation response of graphene with soft substrate”;
15.2014/03/06, Department of Engineering Mechanics, Tsinghua University, Beijing China, “working mechanism of nanoporous energy absorption system under high speed loading”;
16.2013年4月12日清华大学工程力学系邀请报告：“二维材料力学行为的多尺度研究”。
17.2012年5月13日-15日第六届国际分子模拟与信息技术应用学术会议材料科学分会邀请报告：The Application of Solid-liquid Interaction in Nanofluidic System；
18.2012年8月25日参加西安交通大学中美力学研讨会；
19.2011 年7月美国内布拉斯加-林肯大学工程力学系邀请报告：Nanoporous Energy Absorption System；
20.2011年3月18日-20日PKU-YNU Faculty Research Workshop 邀请报告“The Application of Nanofluidic System in Mechanical Energy Damping”；
21.2010年3月1日Department of Mechanical Engineering, North Dakota state university，Topic：Nanoporous Energy Absorption/Damping System；
22.2008年9月9日Seminar in Department of Engineering Mechanics, the University ofNebraska-Lincoln, NE 68588, Sept 9, 2008, Topic: Computational Simulation of the Elastic Property of ZnO Nanofilms；
23.2007年2月15日Seminar in Department of Civil Engineering and Engineering Mechanics, Columbia University, NY 10027 , Topic: Some Recent Studies on the Mechanics of Carbon Nanotubes；
l学术会议报告（Professional Conference Presentations）
1.2018年11月23日至25日，2018年全国固体力学学术会议报告，“石墨烯悬空压痕测试中出现的软化/硬化问题”，哈尔滨，中国。
2.2018 年10 月19-21 日，第19届华东固体力学会议报告“石墨烯压痕测试中的软化/硬化行为”，中国江西南昌。
3.2018年8月19日~8月23日，中国计算力学大会暨国际华人计算力学大会2018（CCCM – ISCM 2018），Indentation response of freestanding two-dimensional materials with an adhesive boundary condition，Nanjing, China。
4.2018/07/22，13th World Congress on Computational Mechanics (WCCM-XIII)，Indentation Response of Freestanding Two-dimensional Materials with an Adhesive Boundary Condition，Columbia University，New York, United States.
5.2018/06/17，First international conference of the mechanics of materials and structures，Indentation tests of two-dimensional materials with substrates，Politecnico di Torino, Torino，Italy。
6.2016/07/25, 12th World Congress on Computational Mechanics (WCCM-XII), Seoul, Republic of Korea, Topic: ” Effectiveness of the Young-Laplace Equation at Nanoscale Based on Numerical Simulation”.
7.2016/06/26, 17th European Conference on Composite Materials (ECCM17), Munich, Germany, Topic: ” Load transfer in a graphene/PDMS nanocomposite under nanoindentation”.
8.2014/08/10, Chinese Conference on Computational Mechanics, China, Topic: ”Multiscale investigations of the mechanical properties of two-dimensional materials”.
9.2014/10/12, Chinese Conference on Solid Mechanics, China, Topic: ” free-standing indentation response of graphene”.
10.2013/12/11, APCOM2013, Singapore, Topic: ”Multiscale investigations of the mechanical properties of graphene based on free-standing indentation”.
11.2013年8月19日~8月21日中国力学大会，会议报告“二维材料力学行为的多尺度研究”。
12.2010年10月16日参加北京振动工程学会学术报告会，会议报告“新型吸能材料”。
13.2011年1月8日参加北京力学会第17次年会，会议报告“纳米多孔能量吸收耗散系统”。
14.2011年8月22日参加中国力学大会-2011暨钱学森诞辰100周年纪念大会，会议报告“纳米尺度环境下的流体行为”以及“纳米多孔能量吸收耗散系统”。
15.2009年11月13日ASME 2009 International Mechanical Engineering Congress & Exposition （IMECE 2009）Lake Buena Vista, Florida, USA会议报告“EVALUATING NUCLEUS EFFECT ON THE CELL MECHANICAL BEHAVIOR”
16.2009年12月13日Third International Conference on Mechanics of Biomaterials & Tissues, Clearwater Beach, Florida, USA, 会议报告：“Evaluating the Mechanical Behaviour of Biological Cell Based on Scanning Probe Indentation”。
17.Nanoenvironments, Mechanics and Materials 2007, Austin, TX；会议报告“Nanoporous Energy Absorption System and Gas-Liquid Interaction”
18.ASME Congress, Chicago, IL 2006；Topic 1: Confined liquid behavior in nanochannels; Topic 2: Mechanical properties of carbon nanotubes in axial and radial directions; Topic 3: Strain sensing with single-walled carbon nanotubes; Topic 4: Buckling of single-walled carbon nanotubes
19.USNCTAM'06, Boulder, CO 2006; On the Thermal-Mechanical Properties of Single-Wall Carbon Nanotubes
20.ASME Congress, Orlando, FL 2005；Topic 1: The Thermal-Mechanical Properties of Single-Walled Carbon Nanotubes; Topic 2: Mechanisms of Nanoindentation on Single-Walled Carbon Nanotubes
承担主要研究课题:
1.2018中国航空基金会，同济-荣泰联合实验室研究项目，人体背部曲线的接触力学测试方法，项目经费10万，主持；
2.2017/1-2017/12，国家重大专项惯约实施管理中心，项目编号：xxxx，基于xxxx输运研究、项目经费30万、已结题、主持。
3.2016/1-2016/12，国家重大专项惯约实施管理中心，项目编号：xxxx，基于xxxx输运特性研究、项目经费30万、已结题、主持。
4.2015/1-2019/12，科技部重大专项, 2015GB113000、基于载能粒子辐照的聚变堆材料快速筛选的等效性研究、项目经费总500万、在研、参加。
5.2012/1-2015/12，国家自然基金面上项目（**），“基于纳米多孔材料的新型能量吸收系统”项目负责人，项目总经费:72万；
6.2013/1-2015/12，纳米研究重大科学研究计划项目，“单分子单细胞水平高分辨实时动态纳米检测技术及应用；课题名称：高分辨、高通量、三维细胞微纳米力学表征技术及其应用” （2013CB933702），项目组成员，所承担项目经费：50万（项目总经费600万）；
7.2012/7-2013/6，863项目2012AA**），“间接驱动xx压缩与直接驱动冲击xx的物理研究”项目组成员，所承担项目经费：10万（项目总经费20万）；
8.2010/1，The Research Project of Nebraska-Lincoln University, “The micromechanical model of neuronal function loss and recovery-microscale mechanism of TBI” 项目负责人，项目总经费: US$10,000;
9.2008-2010, 计算模拟研究对于爆炸冲击波引起的大脑损伤（美国陆军实验室经费，funded by U.S. Army Research Lab, PI: Dr. Chandra）, 项目组成员, （项目总经费US$ 4 million）
10.2005-2007, 纳米生物力学及纳米流体力学的基础研究（美国哥伦比亚大学纳米力学中心经费，funded by Nanomechanics Center in Columbia University, PI: Dr. Xi Chen, Dr. Jeffrey W. Kysar）
11.2000-2004, 计算模拟研究对于纳米材料的加工，性能及应用（美国陆军实验室经费，funded by U.S. Army Research Lab, PI: Dr. Mica Grujicic）;
指导研究生:
博士研究生4人：任云鹏（2019毕业），牛天晓（2017毕业），刘海龙（2016毕业），熊思（2013入学）
硕士研究生2人：刘海龙（2011），王启尧（2012），其中刘海龙获得2013年国家奖学金
教授课程：
板壳力学（本科生专业选修课）32学时
高等数学（文科）64学时
计算固体力学概论（研究生必修）64学时
微纳米尺度测试原理与方法（本科生专业限选）32学时
力学专业英语（本科生专业限选）48学时
Advanced Mechanics of Materials （2009-2010 University of Nebraska-Lincoln）
社会服务：
同济大学2018大飞机班班主任，本科生导师
北京大学工学院2011级本科生班主任，本科生导师
北京大学力学系2011年春季协助筹备系英文网站
北京大学力学系工程力学实验室管理员
科研论文发表（PUBLICATIONS）：
1.任云鹏，曹国鑫*，几何褶皱与晶界偶合作用对石墨烯断裂行为的影响，固体力学学报，2019，评审中。
2.Yunpeng Ren and Guoxin Cao*, Understanding adhesive boundary effect on free-standing indentation characterization of chemical vapor depositiongraphene: Nominal material softening and stiffening, Carbon, 2019, under review。
3.Guoxin Cao*and HuaJian Gao*.Mechanical properties characterization of two- dimensional materials via nanoindentation experiments. Progress in Materials Science, 103: 558-595 (2019). (SCI, IF = 23.75)
4.Lixin. Zhou and Guoxin Cao*. Mechanical behavior of two-dimensional materials investigated by indentation tests. Advances in Mechanics, 48: 201804, (2018).
5.Guoxin Cao*, Yanwei Liuand Tianxiao Niu. Indentation response of two-dimensional materials mounted on different substrates, International Journal of Mechanical Sciences, 137, 96-104 (2018). (SCI, IF = 2.2)
6.Guoxin Cao*and Tianxiao Niu. Finite element modeling of the indentation behavior of two-dimensional materials, Acta Mechanics, DOI: 10.1007/s00707-017-2020-3 (2018). (SCI, IF = 1.851)
7.Tianxiao Niu, Guoxin Cao*，and Chunyang Xiong. Indentation Behavior of the Stiffest Membrane Mounted on a Very Compliant Substrate: Graphene on PDMS, International Journal of Solids and Structures, 132, 1-8 (2018). (SCI, IF = 2.2)
8.Xiong Si. and Guoxin Cao*, Continuum thin-shell model of the anisotropic two-dimensional materials: Single-layer black phosphorus. Extreme Mechanics Letters, 15, 1–9 (2017).
9.Liusi Yang, Tianxiao Niu, Hui Zhang, Wenjing Xu, Mingchu Zou, Lu Xu, Guoxin Cao*and Anyuan Cao*. Self-assembly of suspended graphene wrinkles with high pre-tension and elastic property. 2D Materials, 4, 041001 (2017). (SCI, IF = 6.9)
10.Guoxin Cao*. Nanofluidic Energy Absorption System: A review. Advances in Mechanics, 47: 201706, (2017).
11.Guoxin Cao*. Computational simulations of pressure-driven nanofluidic behavior, SCIENTIA SINICA Physica, Mechanica & Astronomica, 47(7), 070011, (2017).
12.Tianxiao Niu, Guoxin Cao*，and Chunyang Xiong*. Fracture behavior of graphene mounted on stretchable substrate, Carbon,109, 852-859 (2016). (SCI, IF = 6.2)
13.Yunpeng Ren and Guoxin Cao*, Effect of geometrical defects on the tensile properties of graphene, Carbon, 2016, 103, pp125-133. (SCI, IF = 6.2)
14.Hailong Liu and Guoxin Cao*, Effectiveness of the Yang-Laplace equation at nanoscale,Scientific Reports2016, 6, 23936. (SCI, IF = 5.8)
15.Hailong Liu and Guoxin Cao*, Reusable Energy AbsorptionPerformance Based on Nanofluidic Systems,Journal of physical Chemistry C, 2016, 120 (9), pp 5213–5220 (SCI, IF = 4.8)
16.L. Zhou and Guoxin Cao*. Nonlinear anisotropic deformation behavior of graphene monolayer under uniaxial tension, Physical Chemistry Chemical Physics 18, 1657 (2016)(SCI, IF = 4.5)
17.Xiong Si. and Guoxin Cao*, Molecular simulations of bending behavior of single layer MoS2, Nanotechnology 27, 105701 (2016) (SCI, IF = 3.8)
18.Xiong Si. and Guoxin Cao*, Molecular dynamics simulations of mechanical properties of monolayer MoS2. Nanotechnology, 26(18),185705 (2015). (SCI, IF = 3.8)
19.Guoxin Cao*. Atomistic Studies of Mechanical Properties of Graphene, Polymers, 6(9), 2404-2432(2014). (SCI, IF = 3.7)
20.Tianxiao Niu and Guoxin Cao*. Finite size effect does not depend on the loading history in soft matter indentation, Journal of Physics D-Applied Physics, 47 (38), 385303 (2014). (SCI, IF = 2.7)
21.Tianxiao Niu and Guoxin Cao*. Power-law rheology analysis of biological cell properties under AFM indentation measurement, Rsc Advances, 4(55), 29291-29299 (2014). (SCI, IF = 3.8)
22.Hailong Liu and Guoxin Cao*. Super-high Energy Absorption System Based on Nanofluidic Glycerol Solution, Journal of physical Chemistry C,118(43), 25223-25233 (2014). (SCI, IF = 4.8)
23.L. Zhou, Y. Wang and Guoxin Cao*. Estimating the elastic properties of few-layer graphene from free-standing indentation response, Journal of Physics: Condensed Matter, 25, 475301 (2013). (SCI, IF = 2.4)
24.L. Zhou, Y. Wang and Guoxin Cao*. Boundary condition and pre-strain effects on the free standing indentation response of graphene monolayer, Journal of Physics: Condensed Matter, 25, 475303 (2013). (SCI, IF = 2.4)
25.Hailong Liu and Guoxin Cao*. Effects of impact velocity on pressure-driven nanofluid, Journal of Chemical Physics, 139,114701 (2013). (SCI, IF = 3.2)
26.L. Zhou, J. Xue, Y. Wang and Guoxin Cao*. Nanoindentation and deformation mechanism in free-standing monolayer graphene, Carbon, 63, 117-124 (2013).
27.L. Zhou, Y. Wang and Guoxin Cao*. Van der waals effect on the nanoindentation response of free standing monolayer graphene, Carbon, 57,357-362 (2013).
28.L. Zhou, Y. Wang and Guoxin Cao*. Elastic properties of monolayer graphene with different chiralities, Journal of Physics: Condensed Matter, 25, 125302 (2013).
29.Hailong Liu and Guoxin Cao*. Interaction between Mechanical Wave and Nanoporous Energy Absorption System, Journal of physical Chemistry C, 117, 4245-4252 (2013).
30.Guoxin Cao*, Jie Sui and Suli Sun. Evaluating the Nucleus Effect on the Dynamic Indentation Behavior of Cells. Biomechanics and Modeling in Mechanobiology, 12, 55-66(2013).
31.Zigang Ge, Chao Li, Boon Chin Heng, Guoxin Cao, Zheng Yang. Functional biomaterials for cartilage regeneration. Journal of Biomedical Materials Research Part A. 100A, 2526–2536 (2012).
32.Guoxin Cao*. Working Mechanism of Nanoporous Energy Absorption System under High Speed Loading, Journal of physical Chemistry C, 116 (14), 8278–8286 (2012).
33.Guoxin Cao*, and Namas Chandra. Evaluation of Biological Cell Properties Using Dynamic Indentation Method. Physical Review E 81, 021924 (2010).
34.Guoxin Cao, Xi Chen, Zhi-Hui Xu and Xiaodong Li.Measuring Mechanical Properties Of Micro- And Nano-Fibers Embedded In An Elastic Substrate: Theoretical Framework And Experiment. Composites Part B: Engineering, 41, 33-41 (2010).
35.Xi Chen, Guoxin Cao, Aijie Han, Patricia J. Culligan, and Yu Qiao. Nanoscale Fluid Transport: Size and Rate Effects, Nano Letters, 8 (9), 2988–2992 (2008).
36.Guoxin Cao, Yu Qiao, Qulan Zhou, and Xi Chen, Water Infiltration Behaviors in Carbon Nanotubes under Static and Dynamic Loading Conditions. Molecular Simulation 34, 1267-1274 (2008).
37.Guoxin Cao, Yu Qiao, and Xi Chen. The Infiltration Behavior of Water in Carbon Nanotube under External Pressure, Philosophical Magazine Letters. 88, 371–378 (2008).
38.Guoxin Caoand Xi Chen. Self-Assembled Triangular and Labyrinth Buckling Patterns of Thin Films on Spherical Substrates. Physical Review Letters, 100, 036102 (2008).
39.Guoxin Caoand Xi Chen. The Size Dependence and Orientation Dependence of Elastic Property of ZnO Films. International Journal of solids and Structure, 45, 1730–1753, (2008).
40.Liu Ling, Guoxin Cao, and Xi Chen. Mechanisms Of Nanoindentation On Multi-Walled Carbon Nanotube And Nanotube Cluster, Journal of Nanomaterials. 271763, (2008).
41.Guoxin Caoand Xi Chen. The Size Effect Of Nanoindentation On Zno Nanofilms. Journal of Applied Physics, 102, 123513 (2007).
42.Xi Chen and Guoxin Cao. Atomistic Studies of Mechanical Properties of Carbon Nanotube. Journal of theoretical and computational nanoscience, 4, 823-839, (2007).
43.Guoxin Caoand Xi Chen. An Energy Analysis of Size-Dependent Elastic Properties of ZnO Nanofilms. Physical Review B, 76, 165407 (2007).
44.Yu Qiao, Guoxin Cao, and Xi Chen, Effects of gas molecules on nanofluidic behaviors, Journal of the American Chemical Society. 129, 2355-2359 (2007).
45.Guoxin Cao, Jeffrey W. Kysar and Xi Chen, The mean path of dislocations in nanoparticle and nanorod reinforced metal composites and implication for strengthening mechanisms, Mechanics Research Communication, 34, 275–282 (2007).
46.Guoxin Caoand Xi Chen, The effects of chirality and boundary conditions on the mechanical properties of single-walled carbon nanotubes. International Journal of Solids and Structures 44, 5447-5465 (2007).
47.Guoxin Caoand Xi Chen, Buckling Behavior of Single-walled Carbon Nanotubes and a Targeted Molecular Mechanics Approach. PHYSICAL REVIEW B 74, 165422 (2006).
48.Guoxin Cao, Xi Chen and Jeffrey W. Kysar, Radial Breathing Mode of the Deformed Single-Walled Carbon Nanotubes, Journal of Applied Physics 100, 124305 (2006).
49.Guoxin Caoand Xi Chen. The effect of the displacement increment on the axial compressive buckling behaviors of single-walled carbon nanotubes. Nanotechnology 17, 3844–3855 (2006).
50.Yuye Tang, Guoxin Cao, Xi Chen, Jejoong Yoo, Arun Yethiraj and Qiang Cui. A finite element framework for studying mechanical response of macromolecules: Application to the gating of the mechanosensitive channel, MscL. Biophysical Journal, 91, 1248-1263 published as a cover article (2006).
51.Guoxin Cao, Xi Chen and Jeffrey W. Kysar. Thermal vibration and apparent thermal contraction of single-walled carbon nanotubes. Journal of the Mechanics and Physics of Solids, 54, 1206–1236 (2006).
52.Guoxin Caoand Xi Chen. Buckling of single-walled carbon nanotubes upon bending: Molecular dynamics simulations and finite element method. Physical Review B, 73, 155435 (2006).
53.Guoxin Caoand Xi Chen. Mechanisms of nanoindentation on single-walled carbon nanotubes part I: the effect of nanotube length. Journal of Material Research, 21, 1048-1070 (2006).
54.Xi Chen and Guoxin Cao. A new structural mechanics approach of single-walled carbon nanotubes generalized from atomistic simulation, Nanotechnology, 17, 1004-1015 (2006).
55.Guoxin Cao, Yuye Tang and Xi Chen. Elastic properties of Carbon Nanotubes in Radial Direction. Proceedings of the I MECH E Part N, Journal of Nanoengineering and Nanosystems, 219, Number 2, 73-88 (2005).
56.Guoxin Cao, Xi Chen and Jeffrey W. Kysar. Strain sensing with carbon nanotubes: numerical analysis of the vibration frequency of deformed single-walled carbon nanotubes. Physical Review B, 72, 195412 (2005).
57.Guoxin Cao, Xi Chen and Jeffrey W. Kysar. On the apparent thermal contraction of single-walled carbon nanotubes. Physical Review B, 72, 235404 (2005).
58.M. Grujicic, Guoxin Cao, W. N. Roy. Computational analysis of the lattice contribution to thermal conductivity of single-walled carbon nanotubes. Journal of Materials Science, 40(8), 1943-1952 (2005).
59.M. Grujicic, Guoxin Caoand W. N. Roy. Suitability of boron-nitride single-walled nanotubes as fluid-flow conduits in nano-valve applications. Applied Surface Science, 246, 149-158 (2005).
60.M. Grujicic, K. M. Chittajallu, Guoxin Caoand W. N. Roy. An atomic level analysis of conductivity and strength in poly(ethylene oxide) sulfonic acid based solid polymer electrolytes. Materials Science and Engineering B, 117, 187-197 (2005).
61.M. Grujicic, Guoxin Cao, B. Pandurangan and W. N. Roy, Finite element analysis-based design of a fluid-flow control nano-valve. Materials Science and Engineering B, 117, 53-61 (2005).
62.M. Grujicic, Guoxin Cao, and W. N. Roy. A computational analysis of the percolation threshold and the electrical conductivity of carbon nanotubes reinforced polymeric materials. Journal of Materials Science, 39, 4441-4449 (2004).
63.M. Grujicic, Guoxin Cao, and W. N. Roy. A computational analysis of the carbon- nanotube-based resonant-circuit sensors. Applied Surface Science, 229, 316-323 (2004).
64.M. Grujicic, Guoxin Cao, and B. Gersten. Atomic-computations of the lattice contribution to thermal conductivity of single-walled carbon nanotubes. Materials Science and Engineering B, 107, 204-216 (2004).
65.M. Grujicic, Guoxin Cao, and W. N. Roy. Atomistic simulations of solubilization of single-walled carbon nanotubes in toluene. Journal of Materials Science, 39, 2315-2325 (2004).
66.M. Grujicic, Guoxin Cao, and W. N. Roy. Atomistic modeling of solubilization of carbon nanotubes by non-covalent functionalization with poly(p-phenylenevinylene-co-2,5- dioctoxy-m-phenylenevinylene). Applied Surface Science, 227, 349-363 (2004).
67.M. Grujicic, Guoxin Cao, and P. F. Joseph. Multiscale modeling of deformation and fracture of polycrystalline lamellar g-TiAl+a2-Ti3Al alloys. International Journal for Multiscale Computational Engineering, 1, 3-24 (2003).
68.M. Grujicic, Guoxin Cao, A. M. Rao, T. M. Tritt and S. Nayak. UV-light enhanced oxidation of carbon nanotubes. Applied Surface Science, 214, 289-303 (2003).
69.M. Grujicic, Guoxin Cao, R. Singh. The effect of topological defects and oxygen adsorption on the electronic transport properties of single-walled carbon-nanotubes. Applied Surface Science, 211, 166-183 (2003).
70.M. Grujicic, Guoxin Cao. Reactor length-scale modeling of chemical vapor deposition of carbon nanotubes. Journal of Materials Science, 38, 1819-1830 (2003).
71.M. Grujicic, Guoxin Cao, and B. Gersten. Enhancement of field emission in carbon nanotubes through adsorption of polar molecules. Applied Surface Science, 206, 167-177 (2003).
72.M. Grujicic, Guoxin Cao, S. Batchu. Crystal plasticity-based finite element analysis of deformation and fracture of polycrystalline lamellar g-TiAl + a2-Ti3Al alloys. Journal of Materials Science. 38, 307-322 (2003).
73.M. Grujicic, Guoxin Cao, B. Gersten. Optimization of the chemical vapor deposition process for carbon nanotubes fabrication. Applied Surface Science, 199, 90-106 (2002).
74.M. Grujicic, Guoxin Cao, R. S. Miller. Computer modeling of the evolution of dendrite microstructure in binary alloys during non-isothermal solidification. Journal of Materials Synthesis Processing. 10,191-203 (2002).
75.M. Grujicic, Guoxin Cao. Crack growth in lamellar titanium aluminides containing beta phase precipitates. Journal of Materials Science, 37, 2949-2963 (2002).
76.M. Grujicic, Guoxin Cao, B. Gersten. An atomic-scale analysis of catalytically-assisted chemical vapor deposition of carbon nanotubes. Materials Science and Engineering B, 94, 247-259 (2002).
77.M. Grujicic, Guoxin Cao, G. M. Fadel. Effective materials properties: determination and application in mechanical design and optimization. Journal of Materials: Design & Applications, 215, 225-234 (2002).
78.M. Grujicic, Guoxin Cao, R. S. Figliola. Computer simulations of the evolution of solidification microstructure in the LENS (TM) rapid fabrication process. Applied Surface Science, 183, 43-57 (2001).
79.R. S. Miller, Guoxin Cao, M. Grujicic. Monte Carlo simulation of three-dimensional nonisothermal grain-microstructure evolution: Application to LENS rapid fabrication. Journal of Materials Synthesis Processing, 9, 329-345 (2001).
80.Guoxin Cao*, Lianfen Fu, Jianguo Lin, Yonggang Zhang, Changqi Chen. The relationships of microstructure and properties of a fully lamellar TiAl alloy. Intermetallics, 8, 647-653 (2000).
81.Guoxin Cao*, Jianguo Lin, Yonggang Zhang, Changqi Chen. Phase transformation of fully lamellar gamma-TiAl alloys in alpha plus gamma field. Transactions of Nonferrous Metals Society of China, 10, 425-429 (2000).
82.Guoxin Cao*, Jianguo Lin, Yonggang Zhang, Changqi Chen. Influences of grain size and lamellar spacing on the properties of fully lamellar γ-TiAl alloys. Rare Metal Materials and Engineering, 29, 172-176 (2000) (in Chinese).
PUBLICATIONS IN CONFERENCE PROCEEDINGS
1.G. Shailesh, L. Gu, Guoxin Caoand N. Chandra. The Effect of Shock Wave on a Human Head. Proceedings Of The ASME International Mechanical Engineering Congress And Exposition, 2, 339-346(2010).
2.Guoxin Cao, Zhou, You; Lee, Jeong Soon; et al.. COMPUTATIONAL SIMULATION OF THE DEFORMATION OF NEURONAL CELLS, Proceedings of the Asme International Mechanical Engineering Congress and Exposition 2010, Vol 2 Pages: 179-180.
3.Guoxin Cao, Zhou, You; Lee, Jeong Soon; et al.. MECHANICAL MODEL OF NEURONAL FUNCTION LOSS, Proceedings of the Asme International Mechanical Engineering Congress and Exposition 2010, Vol 2 Pages: 185-186.
4.Guoxin Caoand Namas Chandra. Evaluating nucleus effect on the cell mechanical behavior. Proceedings Of The ASME International Mechanical Engineering Congress And Exposition, 2, 503-504 (2010).
5.Guoxin Caoand Namas Chandra. Substrate Effect on Dynamic Indentation Measurement of Biological Cell Properties. Structure-Property Relationships In Biomineralized And Biomimetic Composites, Book Series: Materials Research Society Symposium Proceedings, 1187,121-126 (2009).