张振华，男，博士（后）,二级教授，博士生导师，长沙理工大学纳米结构及纳米器件研究所所长， “湖湘学者（拔尖人才）”特聘教授。 担任J. Am. Chem.Soc.; Nano Lett.; J. Matter. Chem. A; J. Phys. Chem. Lett. 等20余种国际著名刊物审稿。毕业于北京师范大学获硕士学位，毕业于湖南大学获博士学位，也曾在复旦大学表面物理国家重点实验室从事博士后研究。

科研情况：主要研究方向为（1）低维材料物理特性;（2）微纳电子器件输运及设计。近年来先后主持国家自然科学基金项目 (面上项目4项)、湖南省自然科学基金项目等项目研究。 以第1作者或通讯作者身份发表SCI论文100余篇，其中在Adv. Funct. Mater.；Carbon；J. Mater. Chem. C；Phys. Rev. B；Appl. Phys. Lett.等1、2区期刊上发表论文70余篇（1 区论文20余篇；Appl. Phys. Lett.15篇、含封面文章1篇； H因子>25）.

获奖及荣誉称号：（1）湖南省自然科学奖二等奖（排名1）；（2）湖南省优秀博士学位论文奖；（3）湖南省优秀硕士学位论文奖（8篇，指导教师）；（4）湖南省自然科学优秀学术论文一等奖（3篇，排名1）、二等奖（4篇，排名1或2）；（5）湖南省优秀高等教育研究成果奖二等奖（排名1）；（6）湖南省高等教育教学成果二等奖（排名2）；（7）长沙理工大学（中国移动）优秀教学贡献奖（首届）；（8）湖南省“新世纪121人才工程”人才（首批）；（9）交通部“全国交通系统优秀教育工作者”荣誉称号；（10）湖南省“优秀研究生导师”荣誉称号（2019，首届）。

指导学生情况：指导的硕士研究生中，多人获得湖南省研究生创新项目及国家奖学金的资助、评为湖南省优秀毕业生、“长理十星”、“长沙理工大学研究生科研标兵等。也有多人进入名所名校（如：中科院物理所、香港城市大学、复旦大学、武汉大学、重庆大学）攻读博士学位。指导的研究生学位论文中，评为湖南省优秀硕士学位论文8篇。指导本科生参加科研取得良好成绩，学生以第1作者身份在Carbon, Phys. Chem. Chem. Phys., Org. Electron., J .Appl .Phys.等SCI刊物上发表论文18篇。

课题组每年招收物理以及电子科学与技术方向博士生、硕士生若干，欢迎报考。

联系方式：Email: zhzhang@csust.edu.cn,  cscuzzh@163.com.

通讯地址：410114, 长沙市（雨花区）万家丽南路二段960号

长沙理工大学物理与电子科学学院

近年在国际刊物上发表的部分论文 (“*”通讯作者):

[]33] R. Hu, Y. H. Li, Z. H. Zhang*, Z. Q. Fan and L. Sun. O-Vacancy-line defective Ti₂CO₂ nanoribbons: novel magnetism, tunable carrier mobility, and magnetic device behaviors . J. Mater. Chem. C 7, 7745-7759 (2019)

[32] J.K Hu, Z.H. Zhang*, Z.Q.Fan, R.L. Zhou*.Electronic and Transport Properties and Physical Field Coupling Effects for Net-Y Nanoribbons. Nanotechnology.30 485703 (2019)

[31] W. Kuang, R. Hu, Z.Q.Fan, and Z.H Zhang* ^.Spin-Dependent Carrier Mobility and Its Gate-Voltage Modifying Effects For Functionalized Single Walled Black Phosphorus Tubes. Nanotechnology.30, 145201(2019)

[30] R. Hu, Z.Q. Fan, C.H. Fu, L.Y. Nie, W.R. Huang, Z.H. Zhang*. Structural stability, magneto-electronics and spin transport properties of triangular graphene nanoflake chains with edge oxidation. Carbon 126, 93-104(2018) .

 

[29] P.F.Yuan, Z.Q. Fan, Z.H. Zhang*. Magneto-electronic properties and carrier mobility in phagraphene nanoribbons: A theoretical prediction. Carbon 124, 228-237 (2017).

[28] P. F. Yuan, Z. H. Zhang*, Z. Q. Fan and M. Qiu. Electronic structure and magnetic properties of penta- graphene nanoribbons. Phys. Chem. Chem. Phys., 19, 9528-9536 (2017)

 

[27] D. Wang, Z.H. Zhang*, X.Q. Deng, Z.Q. Fan, G.P. Tang. Magnetism and magnetic transport properties of the polycrystalline graphene nanoribbon heterojunctions. Carbon 98, 204 (2016).

[26] Z. Zhu, Z. H. Zhang*, D. Wang, X.Q.Deng, Z.Q.Fan, G.P.Tang. Magnetic structure and magnetic transport characteristics of nanostructures based on armchair-edged graphene nanoribbons. J. Mater. Chem. C 3, 9657 (2015).

[25] J. Li, Z.H. Zhang*, D. Wang, Z. Zhu, Z.Q.Fan, G. P. Tang, and X.Q. Deng. Electronic structures, field effect transistor and bipolar field-effect spin filtering behaviors of functionalized hexagonal graphene nanoflakes. Carbon 69, 142(2014).

 

[24] J.Li, Z.H. Zhang*, M. Qiu,C.Yuan, X.Q. Deng, Z.Q. Fan,G.P. Tang, B. Liang. High- performance current rectification in a molecular device with doped graphene electrodes. Carbon, 80 575(2014).

[23] Z. H. Zhang*, C. Guo, D.J. Kwong, J.Li, X. Q. Deng, and Z.Q. Fan. A Dramatic odd–even oscillating behavior for the current rectification and negative differential resistance in carbon-chain- modified donor–acceptor molecular devices. Adv. Funct. Mater. 23, 2765  (2013)

 

[22] Z. H. Zhang*, C.Guo, G. Kwong, and X. Q. Deng. Electronic transport of nitrogen-capped monoatomic carbon wires between lithium electrodes. Carbon 51, 313 (2013)

[21] Z.Q.Fan*, Z.H. Zhang*, M. Qiu, X.Q. Deng, G.P Tang. The site effects of B or N doping on I-V characteristics of a single pyrene molecular device. Appl. Phys. Lett.101, 073104 (2012)

[20] X.Q Deng, Z.H Zhang*, G. Tang, Z. Fan , M. Qiu, C. Guo. Rectifying behaviors induced by BN-doping in trigonal graphene with zigzag edges. Appl. Phys. Lett.100, 06310（2012）

[19] G. P. Tang, J. C. Zhou*, Z. H. Zhang*, X. Q. Deng, and Z. Q. Fan. Altering regularities of electronic transport properties in twisted graphene nanoribbons. Appl. Phys. Lett.101, 023104 (2012)

[18]C. Guo, Z. H. Zhang*, G. Kwong, J. B. Pan, X. Q. Deng, and J. J. Zhang. Enormously enhanced rectifying performances by modification of carbon chains for D-σ-A molecular devices. J. Phys. Chem. C116, 12900(2012)

[17] J. Li, Z.H. Zhang*, J.J. Zhang, X.Q. Deng. Rectifying regularity for a combined nanostructure of two trigonal graphenes with different edge modifications. Org. Electron.13, 2257 (2012)

[16] M. Qiu, Z. H. Zhang*, Z. Q. Fan, X. Q. Deng, J. B.Pan. Transport properties of a squeezed carbon monatomic ring: a route to negative differential resistance device. J.Phys.Chem.C. 115, 11734(2011)

[15]G. Kwong, Z.H. Zhang*, J.B Pan. Rectifying and negative differential resistance behaviors of a functionalized Tour wire: the position effects of functional groups. Appl. Phys. Lett. 99, 123108 (2011).

[14] J. B. Pan, Z.H. Zhang*, X. Q. Deng, M. Qiu, C. Guo. The transport properties of D-σ-A molecules: A strikingly opposite directional rectification. Appl. Phys. Lett. 98, 013503(2011)

[13] J. B. Pan, Z.H. Zhang*, X. Q. Deng, M. Qiu, C. Guo. Current rectification induced by asymmetrical electrode materials in a molecular device. Appl. Phys. Lett. 98, 092102(2011)

[12] Z.H.Zhang*, X. Q. Deng, X. Q. Tan, M. Qiu, J. B. Pan Examinations into the contaminant -induced transport instabilities in a molecular device. Appl. Phys. Lett. 97，183105（封面文章，http://apl.aip.org/ resource/ 1/applab /v97/i18）(2010)

[11]J. B. Pan, Z.H. Zhang*, X. Q. Deng, M. Qiu, C. Guo .Rectifying performance of D-π-A  molecules based on cyano-vinyl aniline derivatives. Appl. Phys. Lett.97, 203104(2010)

[10] X.Q Deng, Z.H Zhang*, J. Zhou, M. Qiu , G..Tang. Electronic transport of the Silane Chain doped with phosphorus and boron atoms. Appl. Phys. Lett. 97, 143103(2010)

[9] M. Qiu, Z. H. Zhang*, X. Q. Deng, J. B.Pan. End-group effects on negative differential resistance and rectifying performance of a polyyne-based molecular wire. Appl. Phys. Lett .97, 242109(2010)

[8] K-H. Ding*, Z.G. Zhu, Z. H. Zhang, and J. Berakdar. Magnetotransport in an impurity-doped few-layer graphene spin valve. Phys. Rev. B 82, 155143(2010). 

[7] X. Q. Deng, Z.H. Zhang*, J.C Zhou, M Qiu. Length and end group dependence of the electronic transport properties in carbon atomic molecular wires. J.Chem. Phys.132, 124107(2010)

[6] M. Qiu, Z.H. Zhang*, X.Q. Deng, and K.Q. Chen. Conduction switching behaviors of a small molecular device, J.Appl. Phys. 107, 063704 (2010) 

[5] X. Q. Deng, J. C. Zhou*, Z. H. Zhang*, G. P. Tang. Electrode metal dependence of the rectifying performance for molecular devices: A density functional study. Appl. Phys. Lett. 95, 103113 (2009)

[4] X. Q. Deng, J. C. Zhou*, Z. H. Zhang*. Electrode conformation - induced negative differential resistance and rectifying performance in a molecular device. Appl. Phys. Lett. 95, 163109 (2009)

[3] Z. Y. Li, W. Sheng, Z. Y. Ning, Z.H.Zhang, Z. Q. Yang, H. Guo. Magnetism and spin-polarized transport in carbon atomic wires, Phys. Rev. B 80, 115429(2009).

[2] Z. H Zhang*, Jingcui Peng, Huang Xiaoyi. Low-temperature magnetoresistance of individual single- walled carbon nanotubes: A numerical study. Phys. Rev. B 66, 085405 (2002)

[1] Z. H. Zhang*, Jingcui Peng, Hua Zhang. Low-temperature resistance of individual single -walled carbon nanotubes: A theoretical estimation. Appl. Phys. Lett. 79, 3515(2001)