删除或更新信息,请邮件至freekaoyan#163.com(#换成@)

长沙理工大学物理与电子科学学院导师教师师资介绍简介-张振华教授

本站小编 Free考研考试/2021-08-22




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****(拔尖人才)”****。 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.CarbonJ. Mater. Chem. CPhys. Rev. BAppl. 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)





相关话题/科学学院 电子

闂傚倸鍊烽懗鍓佸垝椤栫偛绀夋俊銈呮噹缁犵娀鏌熼幑鎰靛殭闁告俺顫夐妵鍕棘閸喒鎸冮梺鍛婎殕瀹€鎼佸箖濡ゅ懏鏅查幖瀛樼箘閻╁海绱撴担椋庤窗闁革綇缍佸濠氭偄閻撳海顦ч梺鍏肩ゴ閺呮繈鎮¢崒鐐粹拺缂佸娉曢悞鍧楁煙閸戙倖瀚�2濠电姷鏁搁崑鐐哄垂閸洖绠扮紒瀣紩濞差亜惟闁冲搫顑囩粙蹇涙⒑閸︻厼鍔嬫い銊ユ瀹曠敻鍩€椤掑嫭鈷戦柛娑橈工婵箑霉濠婂懎浠辩€规洘妞介弫鎾绘偐瀹曞洤骞楅梻渚€娼х换鍫ュ磹閺嵮€妲堢憸鏃堝蓟閿濆鐒洪柛鎰典簼閸d即姊虹拠鈥虫殭闁搞儜鍥ф暪闂備焦瀵х换鍌毭洪姀銈呯;闁圭儤顨嗛埛鎴︽煕濠靛棗顏╅柍褜鍓欑紞濠囧箖闁垮缍囬柍鍝勫亞濞肩喖姊虹捄銊ユ珢闁瑰嚖鎷�
濠电姷鏁告慨浼村垂瑜版帗鍋夐柕蹇嬪€曢悙濠勬喐瀹ュ棙鍙忛柕鍫濐槹閳锋垿鏌涘☉姗堝伐缂佹甯楁穱濠囶敃閿濆洦鍒涘銈冨灪濡啯鎱ㄩ埀顒勬煏閸繃锛嶆俊顐㈠閺岋絾鎯旈婊呅i梺鍝ュУ閻楃姴鐣烽姀銈呯妞ゆ梻鏅崢鎼佹⒑閸涘﹥绀嬫繛浣冲洦鍊堕柨婵嗘娴滄粓鏌熺€涙ḿ绠栧璺哄缁辨帞鈧綆浜跺Ο鈧梺绯曟杹閸嬫挸顪冮妶鍡楀潑闁稿鎹囬弻宥囨嫚閺屻儱寮板┑锟犵畺娴滃爼寮诲鍫闂佸憡鎸婚悷鈺佺暦椤栨稑顕遍悗娑櫭禍顖氣攽閻愬弶鈻曞ù婊勭箞瀵煡顢楅崟顒€鈧爼鏌i幇顔芥毄闁硅棄鍊块弻娑㈠Χ閸ヮ灝銏ゆ婢跺绡€濠电姴鍊搁弳锝嗐亜鎼淬埄娈曢柕鍥у閸╃偤顢橀悙宸痪婵犳鍨遍幐鎶藉蓟閿熺姴鐐婇柍杞扮劍閻忎線姊洪崨濠勬喛闁稿鎹囧缁樻媴閸濄儳楔濠电偘鍖犻崱鎰睏闂佺粯鍔楅弫鍝ョ不閺冨牊鐓欓柟顖嗗苯娈堕梺宕囩帛濮婂綊骞堥妸銉庣喓鎷犻幓鎺濇浇闂備焦鎮堕崐褏绮婚幘璇茶摕闁绘棁娅i惌娆撴煙缁嬪灝顒㈤柟顔界懇濮婄儤瀵煎▎鎴犘滅紓浣哄У閻楁洟顢氶敐澶樻晝闁冲灈鏅滈悗濠氭⒑瑜版帒浜伴柛妯哄⒔缁瑩宕熼娑掓嫼闂佸湱枪濞寸兘鍩ユ径鎰厸闁割偒鍋勬晶瀵糕偓瑙勬礀缂嶅﹥淇婂宀婃Ъ婵犳鍨伴妶鎼佸蓟濞戞ǚ妲堟慨妤€鐗婇弫鍓х磽娴e搫校閻㈩垳鍋ら崺鈧い鎺嗗亾闁诲繑鑹鹃…鍨潨閳ь剟骞冭瀹曞崬霉閺夋寧鍠樼€规洜枪铻栧ù锝夋櫜閻ヮ亪姊绘担渚敯闁规椿浜浠嬪礋椤栨稒娅栭梺鍝勭▉閸樹粙鎮¤箛娑欑厱闁斥晛鍟粈鈧銈忕岛閺嗘竼e濠电姷鏁告慨浼村垂閸︻厾绀婂┑鐘叉搐閻掑灚銇勯幒宥堝厡闁愁垱娲熼弻鏇㈠幢濡も偓閺嗭綁鏌$仦鍓ф创妤犵偞甯¢獮瀣倻閸℃﹩妫у┑锛勫亼閸婃牜鏁悙鍝勭獥闁归偊鍠氶惌娆忊攽閻樺弶澶勯柛瀣姍閺岋綁濮€閵忊剝姣勯柡浣哥墦濮婄粯鎷呯粙鎸庡€┑鐘灪閿曘垹鐣烽娑橆嚤閻庢稒锚娴滎垶姊洪崨濠勭畵濠殿垵椴搁幆鏃堝閿涘嫮肖婵$偑鍊栭崝妤呭窗鎼淬垻顩插Δ锝呭暞閻撴盯鏌涢妷锝呭闁汇劍鍨块弻锝夋偄閸欏鐝旈梺瀹犳椤︾敻鐛Ο鑲╃闁绘ê宕銏′繆閻愵亜鈧牕煤濠靛棌鏋嶉柡鍥╁亶缂傛岸鐓崶銊р槈鐎瑰憡绻冮妵鍕箻濡も偓閸燁垶顢欓敓锟�20婵犲痉鏉库偓妤佹叏閻戣棄纾婚柣妯款嚙缁犲灚銇勮箛鎾搭棡妞ゎ偅娲樼换婵嬫濞戝崬鍓扮紓浣哄У閸ㄥ潡寮婚妶鍡樺弿闁归偊鍏橀崑鎾澄旈埀顒勫煝閺冨牆顫呴柣妯烘閹虫捇銈导鏉戠闁冲搫锕ラ敍鍛磽閸屾瑧顦︽い锔诲灦椤㈡岸顢橀姀鐘靛姦濡炪倖宸婚崑鎾寸節閳ь剟鏌嗗鍛紱闂佺粯姊婚崢褔寮告笟鈧弻鏇㈠醇濠垫劖效闂佺ǹ楠哥粔褰掑蓟濞戙垹鍗抽柕濞垮劚椤晠姊烘导娆戠暠缂傚秴锕獮鍐ㄎ旈崘鈺佹瀭闂佸憡娲﹂崣搴ㄥ汲閿熺姵鈷戦柛婵嗗椤ユ垿鏌涚€n偅宕屾慨濠冩そ瀹曨偊宕熼崹顐嵮囨⒑閸涘﹥鈷愰柣妤冨█楠炲啴鏁撻悩铏珫闂佸憡娲﹂崜娆撴偟娴煎瓨鈷戦梻鍫熺〒缁犳岸鏌涢幘瀵哥疄闁诡喒鈧枼鏋庨柟閭﹀枤椤旀洘绻濋姀锝嗙【妞ゆ垵妫涚划鍫ュ焵椤掑嫭鍊垫繛鍫濈仢濞呭秹鏌¢埀顒勫础閻戝棗娈梺鍛婃处閸嬫帡宕ョ€n喗鐓曢柡鍥ュ妼楠炴ɑ淇婇崣澶婄伌婵﹥妞藉畷顐﹀礋椤愮喎浜惧ù鐘差儜缂嶆牕顭跨捄鐑樻拱闁稿繑绮撻弻娑㈩敃閿濆棛顦ㄩ梺鍝勬媼閸撶喖骞冨鈧幃娆撴濞戞顥氱紓鍌欒兌婵數鏁垾鎰佹綎濠电姵鑹鹃悙濠囨煥濠靛棙鍣稿瑙勬礋濮婃椽鎳¢妶鍛€惧┑鐐插级閸ㄥ潡骞婂Δ鍐╁磯閻炴稈鍓濋悘渚€姊虹涵鍛涧闂傚嫬瀚板畷鏇㈠箣閿旇棄鈧敻鏌ㄥ┑鍡涱€楁鐐瘁缚缁辨帡鎮╁畷鍥р拰闂佸搫澶囬崜婵嗩嚗閸曨偀妲堟繛鍡楁禋娴硷拷