研究领域或方向
· 1. 力电耦合对柔性金属材料的结构，电子结构和传导性质的影响。
· 2. 热力学和计算机模拟研究尺寸对金属纳米线熔化温度的影响。
· 3. 计算机模拟研究二维材料的结构，电子结构以及带隙调控。
· 4．计算机模拟研究燃料电池的阴极氧气还原反应。
· 工作经历
· 2013/01-至今 西安交通大学，材料科学与工程学院，副教授
· 2009/11-2011/11 西安交通大学，材料科学与工程学院 讲师
· 2008/09-2009/9 美国亚利桑那州立大学，化学与生物化学系 博士后
科研项目
1、 国家自然科学基金面上项目，**、力电耦合下铜基纳米多层膜界面效应和传导性质研究、2015/01-2018/12、80万元、在研、主持。
2、 入选2014年江苏省双创人才 50万元、在研、主持。
3、 陕西省自然科学基金 2014JQ6196 柔性铜纳米线在力电耦合下失效的研究 柔性铜纳米线在力电耦合下失效的研究 2015/01-2017/12、 3万元、在研、主持。
4、 西安交通大学交叉学科 xjj** 2016/01-2018/12、 12万元、在研、主持。
5、 国家自然科学基金面上项目，**、应力致石墨烯类二维晶体奇异形变/相变特征及其机制研究、2013/01-2016/12、80万元、已结题、参与。
6、 国家科技部973项目，2012CB619402、铁性智能材料的高性能化研究——智能材料的统一尺度和多性能研究、2012/01-2016/12、301万元、已结题、参与。
7、 国家自然科学基金青年项目，**、力电耦合对不同尺寸铜纳米线、薄膜传导和电迁移性质的影响、2012/01-2014/12、25万元、已结题、主持。
8、 国家教育部博士点基金新教师基金 002 2012/01-2014/12 4万元、已结题、主持。
9、 西安交通大学新教师科研支持计划 93CLDW** 2010/01-2012/12 已结题、主持。
10、 国家自然科学基金，**可控浸润性表面的仿生构建及其晶格玻尔兹曼理论研究2011/01-2013/12、20万元、已结题、参与。
学术成果
第一或通讯作者在国际、国内核心刊物上发表了50余篇学术论文(Nano Energy 1篇，J. Mater. Chem. C 1篇，Applied Physics Letters 2篇、The Journal of Physical Chemistry 6篇)，其中 IF > 3的论文21篇，曾完成国家自然基金青年基金项目(**)一项，参与国家973计划项目(2012CB619402)和两项国家自然科学基金项目(**, **)。目前主持承担国家自然基金面上项目(**)的研究工作。


主要论著

1. T.T. Li, C. He*, W.X. Zhang* Electric field improved the sensitivity of CO on substitutionally doped antimonene Appl. Surf. Sci. (2018), 427,388 IF =3.105(SCI)
2. M. M. Dong, C. He*, W. X. Zhang*, A tunable and sizable band gap of a g-C₃N₄/ graphene/g-C₃N₄ sandwich heterostructure: a van der Waals density functional study. J. Mater. Chem. C (2017), 5, 3830-3837. (IF= 5.256)
3. M. M. Dong, C. He*. W. X. Zhang,* Tunable electronic properties of arsenene and transition-metal dichalcogenides heterostructures: A first principles calculation，Journal of Physical Chemistry C (2017) 121, 22040 (IF= 4.536)
4. C. He, X. F. Wang and W. X. Zhang* Coupling effects of the electric field and bending on the electronic and magnetic properties of penta-graphene nanoribbons Phys.Chem.Chem.Phys (2017), 19, 18426 IF= 4.123 (SCI)
5. M. Bai, W. X. Zhang*, C. He* Electronic and magnetic properties of Ga, Ge, P and Sb doped monolayer arsenene J solid state chem. (2017) 251, 1 IF= 2.299(SCI)
6. W. X Zhang, M. M. Dong,T. T. Li, J. L. Gong, C. He*, Tunable electronic properties of graphene - fully hydrogenated boron nitride heterostructure: a van der Waals density functional study. Superlattices and Microstructures (2017), 109，23. IF= 2.123
7. W. X. Zhang, J.W. Zhao, W.H. He J.Luan, C. He*, Enhanced hydrophilic and conductive properties of blue phosphorene doped with Si atom Chem. phys. Lett. (2016), 653,42 IF=1.815(SCI)
8. Hua Pan, Yanfei Jian, Yanke Yu, Ningna Chen, Chi He*, Cheng He* Promotional mechanism of propane on selective catalytic reduction of NOx by methane over In/H-BEA at low temperature Appl. Surf. Sci. (2016), 390, 608 IF =3.105(SCI)
9. W. X. Zhang, Y. B. Wang, P. Zhao, P; C. He Tuning the electronic and magnetic properties of graphene-like SiGe hybrid nanosheets by surface functionalization Phys. Chem. Chem. Phys (2016), 18, 26205. IF= 4.123 (SCI)
10. M. X. Xiao, Z.M. Ao T. H. Xu, C. He, H.Y. Song and L.Wang Strain modulating half-metallicity of semifluorinated GaN nanosheets Chem. phys. Lett. (2016), 653,42 IF=1.860(SCI)
11. C. He, X.L. Wu, G. Liu and W.X. Zhang Elastic and transport properties of nanolayered crystalline Cu/amorphous Cu-Zr multilayers Materials and Design (2016), 106, 133 IF =3.997(SCI)
12. C. He, W. X. Zhang, T. Li, L. Zhao and X. G. Wang Tunable electronic and magnetic properties of monolayer MoS2 on decorated AlN nanosheets: a van der Waals density functional study Phys.Chem.Chem.Phys (2015), 17, 23207 IF= 4.123 (SCI)
13. C. He, G. Liu, W.X. Zhang, Z.Q. Shi, S.L. Zhou, Tuning structures and electron transport properties of ultrathin Cu nanowires by size and bending stress using DFT and DFTB methods RSC Advance (2015), 5,22464. IF= 3.708 (SCI)
14. C. He, W.X. Zhang, Z.Q. Shi, J.P. Wang, H. Pan, Effect of bending stress on structures and quantum conduction of Cu nanowires, Applied Physics Letters, (2012), 100, 123107. IF=3.515 (SCI)
15. C. He, L. Qi, W.X. Zhang, H. Pan, Effect of electric and stress field on structures and quantum conduction of Cu nanowires, Applied Physics Letters, (2011), 99, 073105. IF=3.515 (SCI)
16. C. He, W.X. Zhang, J.L. Deng, Electric field and size effects on atomic structures and conduction properties of ultrathin Cu nanowires, The Journal of Physical Chemistry C, (2011), 115, 3327. IF=4.835(SCI)
17. K. Wang, C.J. Zhou, Dan Xi, Z. Q. Shi*, C. He*, H. X. Xia, G. W. Liu*, G. J .Qiao Componet-controllable synthesis of Co(SxSe1-x) nanowires supported by carbon fiber paper as high-performance electrode for hydrogen evolution reaction, Nano Energy (2015) 18, 1 IF = 10.07(SCI)
18. W. X. Zhang, C. He,* T. Li and S. B. Gong Tuning electronic and magnetic properties of zigzag graphene nanoribbons with a Stone–Wales line defect by position and axis tensile strain RSC Advance (2015), 5,33407. IF= 3.84 (SCI)
19. W. X. Zhang, T. Li, S. B. Gong, C. He*, L. Duan Tuning the electronic and magnetic properties of graphene-like AlN nanosheets by surface functionalization and thickness Phys. Chem. Chem. Phys. (2015), 17, 10919. IF= 4.493 (SCI)


20. W.X. Zhang, C. He, Melting of Cu Nanowires: A Study Using Molecular Dynamics Simulation, The Journal of Physical Chemistry C (2010), 114, 871. IF=4.835 (SCI)
21. C. He, W.X. Zhang, Y. Li, The glass transition behaviors of low-density amorphous ice films with different thicknesses, Journal of Chemical Physics (2010), 133, 204504. IF=3.122 (SCI)
22. C. He, X. L. Wu, W.X. Zhang, Y. Li, Size-Dependent Stability of Nonhelical and Helical Copper Nanowires Using Density Functional Theory and Density-Functional-Based Tight-Binding Methods Nanoscience and Nanotechnology Letter (2015), 7, 911. IF= 1.444 (SCI)
23. C. He, W.X. Zhang, Effect of Electric Field on Electronic Properties of Nanogenerators Based on ZnO Nanowires, Nanoscience and Nanotechnology Letter (2013), 5, 286. IF= 1.444 (SCI)
24. C. He, R. Huang, Z.Q. Shi, W.X. Zhang, Coupling of electric field and bending modulated ballistic transport properties of copper nanowires Materials Technology: Advanced Functional Materials (2015), 30, A37. IF= 1.227(SCI)
25. Z.Q. Shi*, Z.L Wei, C He* et al, Synthesis, crystal structure and photoluminescence of novel blue-emitting Eu²⁺-doped (SiC)_x–(AlN)₁^__xphosphors by a nitriding combustion reaction，RSC Advance (2014), 4,62926. IF= 3.708 (SCI)
26. W.X.Zhang*, C.He*, T.Li, et al, First-principles study on the electronic and magnetic properties of armchair graphane/graphene heterostructure nanoribbons Solid State Communications (2015), 211, 23. IF= 1.897(SCI)
27. W.X.Zhang, T.Li, C.He* et al, First-principle study on Ag-2N heavy codoped of p-type graphene-like ZnO nanosheet Solid State Communications (2015), 204, 47. IF= 1.897 (SCI)
28. W. X. Zhang*, Y. X. Bai, C. He* et al, Electronic structure and magnetic properties of N monodoping and (Ag,N) codoped graphene-like ZnO sheet Materials Technology: Advanced Functional Materials (2014) , 29, A118. IF= 0.746 (SCI)
29. C. He, W.X. Zhang, Effect of size and stress field on electronic properties of ZnO nanowires Materials Science Forum (2012) 724, 209. (EI)
30. C. He, W.X. Zhang, D. Li, Q.W. Li, Z.Q.Shi, First-principles investigation on Ag, N codoped in p-type ZnO Materials Science Forum (2012) 724, 114.(EI)
31. W. X. Zhang, C. He, Electroless Ni-W-P/Ni-B duplex coatings on AZ91D magnesium alloy Int. Conf. Mech. Autom. Control Eng. 2010, 3895 (EI)
32. W.X. Zhang;Z.J. Zhou; C. He; G. Li, Chromium-free pretreatment and Ni-P alloys technology on magnesium alloy, Jilin Daxue Xuebao (Gongxueban) (2011) 1, 78. (EI)
33. W.X. Zhang; X. Hu; X.B. Lin; C. He* Zr-catalyzed hydrogen chemisorptions on an Al Surface, Advanced Materials Research, (2011), 197-198, 1069. (EI)
34. W. X. Zhang, Y. X. Bai, C. He, X. L. Wu, First-principle study on the effect of high Ag-2N co-doping on theconductivity of ZnO. Bulletin of Materials Science (2015), 38，747. IF= 0.899(SCI)
35. C. He, P. Zhang, Y. F. Zhu, Q. Jiang, “Structures and quantum conduction of Cu nanowires under electric fields using first-principles” J. Phys. Chem. C(2008) 112 9045-9049 IF=4.52
36. C. He, J. S. Lian, Q. Jiang, “Glass-transition temperature of low density amorphous water and related structures”, J. Phys. Chem. B 111(2007) 11177-11180. IF = 3.603
37. C. He, J. S. Lian, Q. Jiang, “Electronic structures and hydrogen bond network of high-density and very high-density amorphous ices”, J. Phys. Chem. B 109( 2005) 19893-19896. IF = 3.603
38. C. He, J. S. Lian, Q. Jiang, “Electronic structures and hydrogen bond network of ambient water and amorphous ices”, Chem. Phys. Lett. 437(2007) 45-49. IF = 2.28
39. W. X. Zhang, C. He, J. S. Lian, Q. Jiang, “Selected crystallization of water as a function of size”, Chem. Phys. Lett. 421(2006) 251-255. IF = 2.28