龍孟秋,男,1980年7月生,教授,中南大學“獵英學者”,先進材料超微結構與超快過程研究所理論組組長,香港城市大學物理與材料系博士後、香江學者。1999年9月-2003年6月,湖南大學套用物理專業大學本科,獲套用物理學學士學位;2003年9月-2008年5月,湖南大學凝聚態物理專業碩博連續研究生,獲凝聚態物理學博士學位;2008年6月-2010年5月,清華大學化學系博士後;2010年6月至今,中南大學物理與電子學院學院教師。講授《固體物理學》、《數學物理方法》等本科生課程。多年來從事納米結構與材料的電子結構及電荷輸運相關性質的理論研究,獲中國博士後基金、中南大學“升華獵英計畫”、湖南省自科基金、“香江學者計畫”及國家自然科學基金等項目資助。在J. Am. Chem. Soc.、ACS Nano.、Appl. Phys. Lett.、 J. Chem. Phys.、 J. Appl. Phys.、 Phys. Lett. A、Solid State Comm. 等國際著名刊物上發表論文70餘篇,被SCI他引1000餘次。
基本介紹
- 中文名:龍孟秋
- 國籍:中國
- 出生日期:1980年7月
- 職業:教師
主要論著,獎勵,承擔和參與的主要科研項目,成員情況,
主要論著
[1] Meng-Qiu Long, Ling Tang, Dong Wang, Linjun Wang, and Zhigang Shuai, Theoretical predictions of size dependent carrier mobility and polarity in graphene. J. AM. CHEM. SOC., 131: 17728, 2009 (IF:10.677);
[2] Mengqiu Long, Ling Tang, Dong Wang, Yuliang Li, and Zhigang Shuai*, Electronic Structure and Carrier Mobility in Graphdiyne Sheet and Nanoribbons: Theoretical Predictions, ACS Nano, 5, 2593-2600, 2011 (IF:12.066);
[3] Jin Xiao, Meng-Qiu Long*, Xinmei Li, Hui Xu, Han Huang, and Yongli Gao, Theoretical Prediction of Electronic Structure and Carrier Mobility in Single-walled MoS2 Nanotubes, Scientific Reposts, 4, 4327, 2014 (IF: 2.927);
[4] Shen-Lang Yan, Meng-Qiu Long*, Xiao-Jiao Zhang, and Hui Xu, The effects of spin-filter and negative differential resistance on Fe-substituted zigzag graphene nanoribbons, Phys. Lett. A 378,960-965, 2014 (IF: 1.766);
[5] Can Cao, Ling-Na Chen, Meng-Qiu Long*, and Hui Xu, Rectifying Effects in Zigzag Graphene Nanoribbon Heterojunctions with Different Edge Hydrogenations, Physics Letters A 377, 1905-1910, 2013 (IF: 1.766);
[6] Meng-Qiu Long, Ke-Qiu Chen, Lingling Wang, B. S. Zou, and Z. Shuai, Negative differential resistance induced by intermolecular interaction in a bimolecular device. Appl. Phys. Lett., 91:233512, 2007;(IF: 3.794)
[7]Meng-Qiu Long, Ke-Qiu Chen, Lingling Wang, Wan Qing, B. S. Zou, and Z. Shuai, Negative differential resistance behaviors in porphyrin molecular junctions modulated with side groups. Appl. Phys. Lett., 92: 243303, 2008 (IF: 3.794);
[8] Can Cao, Ling-Na Chen, Meng-Qiu Long*, Wei-Rong Huang, and Hui Xu,Electronic transport properties on tansiton-metal terminated zigzag graphene nanoribbons, J. Appl. Phys. 111, 113708, 2012 (IF:2.1);
[9] Jinyang Xi, Mengqiu Long, Ling Tang, Dong Wang and Zhigang Shuai*, First-principles prediction of charge mobility in carbon and organic nanomaterials, Nanoscale, 4, 4348, 2012 (IF:6.233);
[10] Ming-Jun Li, Meng-Qiu Long*, Ke-Qiu Chen, and Hui Xu, Fluorination effects on the electronic transport in Dithiophene-Tetrathiafulvalene (DT-TTF) molecular junctions, Solid State Communication, 157,62-67, 2013 (IF:1.543);
[11] Ming-Jun Li, Hui Xua, Ke-Qiu Chen, Meng-Qiu Long*, Electronic transport properties in benzene-based heterostructure:Effects of anchoring groups, Physics Letters A, 376, 1692–1697, 2012 (IF:1.766);
[12] Xiao-Jiao Zhang, Ke-Qiu Chen, Li-Ming Tang,Meng-Qiu Long*, Electronic transport properties on V-shaped-notched zigzag graphene nanoribbons junctions, Phys. Lett. A,375, 3319-3324, 2011 (IF: 1.766);
[13] Li Xin-mei, Long Meng-qiu*, Cui Li-lin, Xiao Jin, and Xu Hui, Electronic and transport properties of V-shaped defect zigzag MoS2 nanoribbons, Chinese Physics B, Vol. 23, No. 4, 04XXXX, 2014 (IF:1.148);
[14] Ming-Jun Li, Meng-Qiu Long*, and Hui Xu, Effects of the bridging bond on electronic transport in single-molecule devices, Chinese Physics Letters 30, 087201, 2013 (IF:0.811);
[15] LILING CUI, BINGCHU YANG, XINMEI LI, JUN HE, and MENGQIU LONG*, Electronic transport properties of transition metal (Cu, Fe) phthalocyanines connecting to V-shaped zigzag graphene nanoribbons, Int. J. Mod. Phys. B 28, 1450019, 2014 (IF:0.358);
[16] X.Z. Wu, M. Q. Long*, L.N.Chen, C.Cao, S.S.Ma, H.Xu, The effects of side groups on the electronic transport properties of carbon chain molecular devices, Physica E, 45, 82-85, 2012 (IF:1.522);
[17]X. Z. Wu, L. N. Chen, C. Cao, W. R. Huang, H. Xu, and M. Q. Long*, The effect of asymmetrical electrode on the transport properties of molecular device, Physica B, 411, 131–135, 2013 (IF:1.327)
[18] Xiao-Jiao Zhang, Meng-Qiu Long, Ke-Qiu Chen, Z. Shuai, Qing Wan, B. S. Zou, and Yan Zhang, Electronic transport properties in doped C60molecular devices. Appl. Phys. Lett., 94: 073503, 2009 (IF: 3.794);
[19] Meng-Qiu Long, Lingling Wang, Ke-Qiu Chen, Xiao-Fei Li, B. S. Zou, and Z. Shuai, Coupling effect on the electronic transport through dimolecular junctions. Physics Letters A, 365: 489-494, 2007 (IF: 1.766);
[20] Meng-Qiu Long, Lingling Wang, Ke-Qiu Chen, Effects of structural and central metal ions modification on the electronic transport properties of porphyrin molecular junctions. Modern Physics Letter B, 22, 661–670, 2008 (IF:0.479)
[21]Liu, B;Zou, YP;Long, MQ;He, YH;Zhong, H;Li, YF, Synthesis and photovoltaic properties of a solution-processable organic molecule containing dithienylbenzotriazole and triphenylamine, SYNTHETIC METALS, 162(7-8),630-635, 2012 (IF:2.109);
[22] Tang Ling, Long Meng-Qiu, Wang Dong & Shuai ZhiGang, The role of acoustic phonon scattering in charge transport in organic semiconductors: a first-principles deformation-potential study, Science in China: Series B Chemistry, 52, 16469-1652, 2009 (IF:1.327);
[23] Dong Wang, Ling Tang, Meng-Qiu Long, and Zhigang Shuai, First-Priciples Investigation of Organic Semiconductors for Thermoelectric Applications, J. Chem. Phys., 131:224704,2009 (IF:3.164);
[24] Wang Dong, Tang Ling, Long Mengqiu, Shuai Zhigang*, Anisotropic Thermal Transport in Organic Molecular Crystals from Nonequilibrium Molecular Dynamics Simulations, J. Phys. Chem. C, 115(13), 5940-5946, 2011 (IF:4.814);
[25] Xiao-Fei Li, Ke-Qiu Chen, Lingling Wang, Meng-Qiu Long, B. S. Zou, and Z. Shuai, Effect of length and size of heterojunction on the transport properties of carbon-nanotube devices, Appl. Phys. Lett., 91:133511, 2007 (IF:3.794);
[26] Xiao-Fei Li, Ke-Qiu Chen, Lingling Wang,Meng-Qiu Long, B. S. Zou, and Z. Shuai, Effect of intertube interaction on the transport properties of a carbon double-nanotube device, J. Appl. Phys., 101: 064514, 2007 (IF:2.1).
獎勵
[1] 龍孟秋,入選2013年度“Hong Kong Scholars Program”;
[2] 張小姣,陳克求,龍孟秋, Electronic transport properties in doped C60 molecular devices,湖南省科協,湖南省自然科學優秀學術論文,一等獎,2012年;
[3] 龍孟秋,入選2011年度“中南大學升華獵英學者計畫”;
[4] 龍孟秋,湖南大學“優秀博士畢業論文”,2009年。
承擔和參與的主要科研項目
(1) 石墨烯納米帶P-N結的理論設計理念,國家自然科學基金,No: 21103232, 2012.1-2014.12,25萬元,主持
(2) 有機納米結構中電荷輸運性質的第一性原理研究,中南大學“升華獵英計畫”,2011.9-2016.9,50萬元,主持
(3) 石墨炔材料的載流子遷移率的計算與功能器件設計的理論研究,湖南省自科基金,2014-2016,4萬元,主持
(4) 石墨烯和拓撲絕緣體的理論研究,“香江學者計畫”,2014-2015,10萬元,主持
(5) 新型有機自旋閥器件的理論設計及電荷性質機理研究,國家自科基金青年項目, 2014-2016,25萬,參與
(6) 有機自旋器件的理論設計與自旋輸運機理研究,中南大學“青年助推”項目,2011.7-2012.7,5 萬元,主持
(7) 有機半導體中自旋的注入和反轉基本機理,國家自然科學基金,2012.1-2015.12,60萬元,參與
(8) 第二類半導體納米晶異質結構的空穴自旋弛豫動力學研究,國家自然科學基金,2012.1-2015.12,62萬元,參與
成員情況
副教授:龍孟秋 (組長),李新梅
講師: 曹粲,李明君,伍曉瓚,歐陽俊(在讀博士),崔麗玲(在讀博士)
博士後:張小姣
博士生:嚴深浪,肖金,張丹
碩士生:鄒運,曹航
本科生:朱博,楊小雨,孟東霄,陳歌,鄭東超,喬藝,程鵬程
b、研究條件
曙光天闊高性能計算平台,含網路伺服器、計算管理伺服器,10個一般計算節點和一個胖節點,392個高性能計算核和768G記憶體,另有曙光DS600-G10磁碟陣列存儲,含12塊2T 企業級SATA硬碟並,配有infiniband高速光纖通信交換機,理論計算速度約4萬億次每秒;並配有VASP,ATK,SETFOS等商業計算軟體,平台總經費約100萬元。
c、主要研究領域
(1) 低維納米材料與器件載流子輸運性質研究
(2) 分子尺度納米電子學
(3) 有機光電器件的理論設計
(4) 介觀結構中的自旋和電荷輸運
(5) 類石墨烯結構中的自旋-軌道耦合和自旋霍爾效應