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龙孟秋
个人简介

龙孟秋( mqlong@csu.edu.cn ),男,1980年7月生,湖南宁乡人,教授,博士生导师,中共党员。现任中南大学物理与电子学院院长助理,“超微结构与超快过程”湖南省重点实验室理论研究室主任,先进材料超微结构与超快过程研究所“自旋电子学”研究团队召集人,中南大学“药剂物理学”实验室负责人。

1999.9-2008.5,先后获湖南大学物理学学士学位和凝聚态物理学博士学位;

2008.6-2010.5,清华大学化学系博士后;

2010.6 至今,中南大学物理与电子学院学院教师;

2011.9 晋升副教授;

2013.12-2015.12,香港城市大学物理与材料科学系“香江学者”;

2015.9 晋升教授。

讲授《大学物理》、《固体物理学》、《数学物理方法》等本科生课程及《凝聚态物理理论》博士生课程。

多年来从事纳米结构与材料的电子结构及电荷输运相关性质的理论研究,在J. Am. Chem. Soc.、ACS Nano.、J. Phys. Chem.Lett.、Appl. Phys. Lett.、 J. Chem. Phys.、 J. Appl. Phys.、 J. Phys. Chem.C、Sci. Rep.等国际著名刊物上发表论文70余篇,被SCI他引1000余次。获国家自然科学基金面上项目、青年项目、“香江学者计划”、湖南省自科基金、中南大学“升华猎英计划”、“创新驱动计划”等项目资助,2011-2016年累计获得科研经费300余万元。


课题组情况介绍

a、成员情况

教授:龙孟秋

副教授:李新梅,张小姣

讲师: 曹粲,李明君,杨开巍,吴迪,肖金,张丹

博士后: 潘长宁,何勇菊

博士生:易秀英,李冬德, 曾波文,董玉兰

硕士生:朱博,赵虹,张仕东,彭丹丹

b、研究条件

1、曙光天阔高性能计算平台,理论计算速度约4万亿次每秒;并配有VASP,ATK,SETFOS等商业计算软件,平台总经费约100万元。

2、200平米的纳米生物药剂实验室,配备先进的液相色谱、气相色谱仪器等;

3、基于GPU加速的高性能计算服务器PWMAT;

4、总计超过80平米的舒适办公空间。


欢迎本科生、硕士生、博士生、博士后加盟!

Email:
mqlong@csu.edu.cn




2017年上半年:《数学物理方法》1-16周,周一,3,4节课,周三,1,2节,C座311;1-16周单周,周五,3,4节,B座502.

2017年下半年:《数学物理方法》1-18周, 周二,1,2,5,6节,B座503;周四,1,2节,B504; 周五,3,4节,B319.


科研方向
_________________________________________________________________________________________


理论研究方向:

(1) 低维纳米材料与器件载流子输运性质研究

设计一系列新型纳米结构,采用第一性原理结合玻尔兹曼输运理论,预测其电子结构和电荷输运特征,为功能纳米器件的设计提供理论基础;

(2) 分子尺度纳米电子学

采用密度泛函理论结合非平衡格林函数方法研究纳米器件的电荷、自旋输运行为,从理论上设计多功能耦合的量子器件;

(3) 能源材料的理论设计及光电转换机理研究

设计新型有机-无机钙钛矿结构,对其稳定性、能带特征、光电转换效率等进行理论预测和调控;

(4) 介观结构中的多效应耦合机制研究

采用第一性原理计算,对纳米结构如石墨烯、石墨炔、磷烯、MPX3等的电荷、自旋、热输运行为进行理论性能预测和机理分析;

(5) 类石墨烯结构中的自旋-轨道耦合和自旋霍尔效应

设计具有新奇非平庸拓扑态的新型二维纳米结构,理论研究其自旋-轨道耦合及自旋霍尔效应。

实验研究方向:

(1) 纳米药剂材料的制备

目前主要研究介孔二氧化硅纳米载体的制备及其对药物的装载、释放和递送;

(2) 脂质体在超声条件下对疏水性药物的包载研究

研究药物载体材料的包载性、生物降解性等行为;


学术成果
_________________________________________________________________________________________


近年主持的主要科研项目

国家自科基金:

1. 磷烯纳米结构的自旋输运性质及其器件设计的理论研究, 21673296 直接经费 65万元 2017-2020年;

2. 石墨烯纳米带P-N结的理论设计理念,21103232, 2012-2014,经费25万元 (2015年1月结题);

3. “ NSFC- 广东联合基金(第二期)超级计算科学应用研究专项资助”, 20万机时,2015-2017。

省部级科学基金:

1. 湖南省基金:石墨炔材料的载流子迁移率计算与功能器件设计的理论研究,14JJ3026,经费4万元, 2014-2016(2015年6月结题)

2. 湖南省科技计划:分子磁铁器件自旋输运性质的理论研究,2015RS4002 2015-2017, 5万元,

3. 博士后基金:二硫化钼纳米带的自旋相关电荷载流子输运性质的第一性原理研究2014M552145,2013-2015,经费5万元(2016年4月结题)。

4. 香江学者计划:“石墨烯自旋与拓扑绝缘体” ,XJ2013003, 2014-2015;30万RMB,30万HKD(2016年1月结题)

其他:

1. 中南大学科研助推基金: 5万元,2011-2012,(2012年结题)

2. 中南大学升华猎英计划: 有机半导体电荷输运理论研究,2011-2016,50万元,(2016年8月结题)

3. 中南大学教师基金: 二硫化钼材料的电荷传输机理及其自旋器件设计的理论研究2014JSJJ022 20万元,2015-2016

4. 中南大学创新驱动计划:

磷烯纳米结构中自旋输运性质的相关理论问题研究 2016CX039 70万元,2016-2017

发表相关期刊论文(“*”为通讯作者)

2017

[76] Chang-Ning Pan, Meng-Qiu Long*, Jun He, The modulated thermal transport for exural and in-plane phonons in double-stub graphene nanoribbons, Accepted by Results in Physics

[75] Dan Zhang, Mengqiu Long*, Xiaojiao Zhang, Jun Ouyang, Hui Xu, Perfect spin filtering, rectifying and negative differential resistance effects in armchair graphene nanoribbons with poor and rich electrons doping, Accepted by Journal of Applied Physics

[74] Mingjun Li, Dan Zhang, Yongli Gao, Can Cao, and Mengqiu Long*, Half-metallicity and spin-polarization transport properties in transition-metal atoms single-edge-terminated zigzag α-graphyne nanoribbons. Organic Electronics, 44, 168-175(2017);

[73] Yongju He, Jing Li, Mengqiu Long*, Shuquan Liang, Hui Xu, Tuning pore size of mesoporous silica nanoparticles simply by varying reaction parameters, Journal of Non-Crystalline Solids 457, 9-12 (2017);

[72] Chen-Chen Zhao, Shi-Hua Tan a, Xiao-Fang Peng, Xin-Jun Wang, Mengqiu Long, Spin filter type transformation in Sn-phthalocyanine, Organic Electronics 43 (2017) 47-54;

[71] Liu, Qi; OuYang, Fangping; Yang, Zhixiong; Peng, Shenglin; Zhou, Wenzhe; Zou, Hui; Long, Mengqiu; Pan, Jiangling,Electronic properties and transistors of the NbS2-MoS2-NbS2 nanoribbon heterostructure, Nanotechnology 2016, 28(7):075702;

[70] Yu-XiangPeng, Meng-Dong He, Ze-JunLi, Kai-JunWang, ShuiLi, Jian-BoLi, Jian-Qiang Liu, MengqiuLong, Wei-Da Hu, XiaoshuangChen, Graphene ribbon coupled tunable enhanced transmission through metallic grating, Optics Communications, 382, 86–92 (2017)

[69] Yufeng Liu, Xinfeng Zheng, Qianqian Li, Mengqiu Long, Jingshan Hou, Na Zhang, Guoying Zhao, Yongzheng Fang, A non-vacuum solution route to prepare amorphous metal oxides thin films for Cu2ZnSn(S,Se)4 solar cells, Journal of Alloys and Compounds 695, 3146-3151 (2017)

[68] Fang Xie, Zhi-Qiang Fan, Xiao-Jiao Zhang, Jian-Ping Liu, Hai-Yan Wang, Kun Liu, Ji-Hai Yu, Meng-Qiu Long, Tuning of the electronic and transport properties of phosphorene nanoribbons by edge types and edge defects, Organic Electronics 42, 21-27 (2017)

[67] Zhi-Qiang Fan, Wei-Yu Sun, Xiang-Wei Jiang, Zhen-Hua Zhang a, * Xiao-Qing Deng, Gui-Ping Tang, Hai-Qing Xie, Meng-Qiu Long, Redox control of magnetic transport properties of a single anthraquinone molecule with different contacted geometries, Carbon 113, 18-25 (2017)

2016

[66] Zeng, Bowen; Li, Mingjun; Zhang, Xiaojiao; Yi, Yougen; Fu, Liping; Long, Mengqiu*, First-Principles Prediction of the Electronic Structure and Carrier Mobility in
Hexagonal Boron Phosphide Sheet and Nanoribbons. Journal of Physical Chemistry C, 120 (43), 25037–25042 (2016).

[65] Jun Ouyang, Mengqiu Long*, Xiaojiao Zhang, Dan Zhang, Jun He, and Yongli Gao,
Modulating the spin transport behaviors in ZBNCNRs by edge hydrogenation and position of BN chain, AIP Advance 6(3):035116, 2016 (March )

[64] Dan Zhang, Mengqiu Long*, Fang Xie, Jun Ouyang, Hui Xu, and Yongli Gao, Hydrogenations and electric field induced magnetic behaviors in armchair silicene nanoribbons,
Scientific Reports, 6,23677 (2016).(March 30)

[63] Jin Xiao, Mengqiu Long*, Chao-Sheng Deng, Jun He, Li-Ling Cui and Hui Xu, Electronic structures and carrier mobilities of blue phosphorus nanoribbons and nanotubes: a first principles study. Journal of Physical Chemistry C, 120, 46384646, 2016 (February 12, 2016)

[62] Dan Zhang, Mengqiu Long*, Xiaojiao Zhang, Jun Ouyang, Hui Xu, “Spin-resolved transport properties in zigzag-graphyne nanoribbons with symmetric and asymmetric edge fluorinations”,
RSC Advances, 6, 15008-15015, 2016 .

[61] Li-Ling Cui, Meng-qiu Long*, Xiaojiao Zhang, Xin-Mei Li, Dan Zhang, and Bing-Chu Yang*, Spin-dependent transport properties of hetero-junction based on zigzag graphene nanoribbons with edge hydrogenation and oxidation, Phys. Lett. A, 380, 730-738, 2016. (15 Feb)

[60] Xin-Mei Li, Meng-Qiu Long*, Li-Ling Cui, Kai-Wei Yang, Dan Zhang, Jia-Feng Ding, Hui Xu, Effects of line defects on spin-dependent electronic transport of zigzag MoS2 nanoribbons,
AIP Advance 6, 015015 (2016) (Jan. 26)

[59] Jing Zeng, Ke-Qiu Chen, Xiaohui Deng and Mengqiu Long, Light-driven strong spin valve effects in an azobenzene-based spin optoelectronic device, Journal of Physics D: Applied Physics, 49, 415104 (2016)

[57] Qingtian Zhang, K S Chan and Mengqiu Long, Nearly perfect valley filter in silicene, J. Phys.: Condens. Matter 28 (2016) 055301.( Jan. 13)

[56] Yongzheng Fang, Fengxin Liu, Jingshan Hou, Yan Zhang, Xinfeng Zheng, Na Zhang, Guoying Zhao, Meisong Li, Guozhang Dai, Mengqiu Long, Yufeng Liu, Photoluminescence properties of blue light excited Ca8La2(PO4)6O2: Eu3 red phosphors, Journal of Luminescence 177 (2016) 280–285.

[55] Jing Zeng, Ke-Qiu Chen, Mengqiu Long, Hydrogen tautomerization: A simple approach to tune spin-filtering effects in a quinone-based spintronic device. Organic Electronics 35 (2016) 12-16;

[54] Shuang-Shuang Ding, Wei-Qing Huang, Yin-Cai Yang, Bing-Xin Zhou, Wang-Yu Hu, Meng-Qiu Long, P. Peng, and Gui-Fang Huang, Dual role of monolayer MoS2 in enhanced photocatalytic performance of hybrid MoS2/SnO2 nanocomposite. Journal of Applied Physics 119, 205704 (2016);

[53] Zhiyong Wang, Yayun Zhao, Mengyao Sun, Jianrong Xiao, Maowang Lu, Liu Wang, Yaping Zeng, Mengqiu Long, The effects on the electronic properties of BN nanoribbon with C-chain substitution doping. Solid State Communications 240 (2016) 33–36;

[52] Jing Wang, Mengqiu Long, Wen-Sheng Zhao, Yue Hu, Gaofeng Wang, and K S Chan, A valley and spin filter based on gapped graphene. J. Phys.: Condens. Matter 28 (2016) 285302.

[51] Fang Xie, Zhi-Qiang Fan, Xiao-Jiao Zhang, Jian-Ping Liu, Hai-Yan Wang and Meng-Qiu Long, Tunable negative differential resistance in a single cruciform diamine molecule with zigzag graphene nanoribbon electrodes. RSC Adv., 2016, 6, 84978;

[50] Yun Ren, Jun He, Zhi-Qiang Fan, Xiang Zhu, Yi Liu, Meng-Qiu Long and Ke Xiao, Spin polarization current induced by hydrogen hybrid within closed hexagon graphene nanoribbon devices, Modern Physics Letters B Vol. 30, No. 27 (2016) 1650333.

2015

[49]
Hui Zeng, Meng-Qiu Long, Ottorino Ori, Mihai V. Putz, and Jeanlex S. de Sousa, Computational Modeling of Physical and Chemical Properties of Nanomaterials, Journal of Nanomaterials Volume 2015 (2015), Article ID 915820, 2015.

[48]
Dan Zhang, Mengqiu Long*, Xiaojiao Zhang, and Hui Xu, High performances bipolar spin filtering and switching functions of poly-(terphenylene-butadiynylene)s between zigzag graphene nanoribbon electrodes, RSC Advances, 5, 96455-96463, 2015.

[47]
Jin Xiao, Mengqiu Long*, Xiaojiao Zhang, Dan Zhang, HuiXu, and K. S. Chan First-principles prediction of the charge mobility in black phosphorus semiconductor nanoribbons, Journal of Physical Chemistry Letters, 6, 4141-4147, 2015

[46]
Pan Wang, Ma Zhou, Guang Liu, Yiman Liu, Meng-Qiu Long, and Guanghui Zhou, Spin- and valley-dependent transport properties for metal-silicene-metal junctions, Eur. Phys. J. B (2015) 88: 243

[45] Jun Ouyang, Dan Zhanga, Mengqiu Long*, Xiaojiao Zhang, Hui Xu, “Electronic structrues and transport properties of zigzag BNC nanoribbons with different combinations of BN and graphene nanoribbons”, Computational Condensed Materials, 4, 40-45, 2015;

[44]
Can Cao, Mengqiu Long*, and Xiancheng Mao, "Symmetry-dependent spin transport properties and spin-lter effects in zigzag-edge germanene nanoribbons", Journal of Nanomaterials, V2015, ID 810659

[43]
Can Cao, Mengqiu Long*, Xiancheng Mao, “Giant magnetoresistance effect, rectifying performance and spin lters in graphene-based heterostructure”, Journal of Computational and Theoretical Nanoscience, 12, 1-6, 2015.

[42] X
iaojiao Zhang, Keqiu Chen, Mengqiu Long*, Jun He, and Yongli Gao, "Effect of length and negative differential resistance behavior in conjugated molecular wire tetrathiafulvalene devices", Mod. Phys. Lett. B, Vol. 29, No. 13 (2015) 1550106.

[41] Jin Xiao, Mengqiu Long*, Xiaojiao Zhang, Jun Ouyang, Hui Xu, and Yongli Gao, "
Theoretical prediction on the charge carrier mobility in 2D Phosphorous sheets", Scientific Reports, 5, 09961, (2015);

[40]
Can Cao, Mengqiu Long*, Xiaojiao Zhang, and Xiancheng Mao, " Giant magnetoresistance and spin-filtering effects in zigzag graphene and hexagonal boron nitride based heterojunction ", Phys. Lett. A, 379,1527-1531 (2015);

[39]
Yun Zou, Mengqiu Long*, Mingjun Li, Xiaojiao Zhang, Qingtian Zhang, and Hui Xu, "Control of electronic transport in nanohole defectivezigzag graphene nanoribbon by means of side alkene chain", RSC Advance, 5, 19152-19158 (2015);

[38] Jin Xiao, Mengqiu Long*, Mingjun Li, Xinmei Li, Hui Xu, and Kwoksum Chan, "Carries mobility of MoS2 nanoribbons with the edge chemical modification",
Phys. Chem. Chem. Phys. 17, 6865 – 6873 (2015)

[37] Junliang Yang, Noel Clark, Mengqiu Long, Jian Xiong, David J. Jones, Bingchu Yang, Conghua Zhou, “Solution stability of active materials for organic photovoltaics”, Solar Energy 113, 181-188 (2015);

[36]
Dan Zhang, Mengqiu Long*, Xiaojiao Zhang, Fangping Ouyang, Mingjun Li, and Hui Xu, "Designing of spin-filtering devices in zigzag graphene nanoribbons heterojunctions by asymmetric hydrogenation and B-N doping", J. Appl. Phys. 117, 014311 (2015);

2014

[35]
Yiman Liu, Xiaoying Zhou, Ma Zhou, Meng-Qiu Long and Guanghui Zhou, "Full spin- and valley-polarization by electric field in a magnetically confined channel on silicene sheet", J. Appl. Phys.116,244312,2014

[34] Tong Chen, Lingling Wang, Xiaofei Li, Kaiwu Luo, Liang Xu, Quan Li, Xianghua Zhang; and Mengqiu Long, "Spin-dependent transport properties of a chromium porphyrin-based molecular embedded between two graphene nanoribbon electrodes", RSC Advances 4,60376, 2014

[33] Dan Zhang, Mengqiu Long*, Xiaojiao Zhang, Can Cao, Hui Xu, Mingjun Li, and Kowksum Chan "Bipolar spin-filtering, rectifying and giant magnetoresistance effects in zigzag silicene nanoribbons with asymmetric edge hydrogenation", Chemical Physics Letters 616–617, 178–183, 2014

[32] Jin Xiao, Meng-Qiu Long*, Xin-Mei Li, Qing-Tian Zhang, Hui Xu, and K. S. Chan "Effects of Van der Waals interaction and electric field on the electronic structure of bilayer MoS2", J. Phys.: Condens. Matter
26, 405302, 2014

[31] SHENLANG YAN, MENGQIU LONG*, XIAOJIAO ZHANG, JUN HE, HUI XU and YONGLI GAO, "
Spin-filtering, rectifying and negative differential resistance behaviors in Co(dmit)2 molecular devices with monatomic (C, Fe, Au) electrodes ", Spin Vol. 4, No. 2, 1440016, 2014

[30] Li-Ling Cui, Bing-Chu Yang*, Xin-Mei Li, Can Cao, and Meng-Qiu Long*, "Effects of symmetry and spin-configuration on spin-dependent transport properties o f ZGNR/FePc/ZGNR devices",
J. Appl. Phys. 116, 033701, 2014.

[29] Xin-Mei Li, Meng-Qiu Long*, Li-Lin Cui, Jin Xiao, Xiao-Jiao Zhang, and Hui Xu,
"Effects of V-shaped edge defect and H-saturation on spin-dependent electronic transport of zigzag MoS2 nanoribbons ", Phys. Lett. A, 378, 2701-2707, 2014

[28] Shenlang Yan, Meng-Qiu Long*, Xiaojiao Zhang, Jun He, Hui Xu, and Keqiu Chen, "Effects of the magnetic anchoring groups on spin-dependent transport properties of Ni(dmit)2 device", Chem. Phys. Lett.,
608, 28-34, 2014

[27] 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 Reports, 4, 4327, 2014;

[26]
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;

[25] 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, 047307, 2014;

[24] 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;

2013

[23] C
an 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;

[22] 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;

[21] 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;

[20] 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;

[19] YAN Shenlang, LONG Mengqiu, HUANG Weirong, XU Hui, Spin transport properties of quaterthiophene molecular junctions. Journal of Central South University (Science and Technology), Vol.44 No.11, 4436-4441, 2013;

2012

[18] 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;

[17] 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;

[16] 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;

[15] 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;

[14]
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;

2011

[13] 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;

[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;

[11] 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;

2009

[10] 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;

[9] 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;

[8] 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;

[7] Xiao-Jiao Zhang, Meng-Qiu Long, Ke-Qiu Chen, Z. Shuai, Qing Wan, B. S. Zou, and Yan Zhang, Electronic transport properties in doped C60 molecular devices. Appl. Phys. Lett., 94: 073503, 2009;

2008

[6] 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;

[5] 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;

2007

[4] 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;

[3] 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;

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[1] 龙孟秋,入选2013年度“Hong Kong Scholars Program”;

[2] 张小姣,陈克求,龙孟秋, Electronic transport properties in doped C60 molecular devices,湖南省科协,湖南省自然科学优秀学术论文,一等奖,2012年;

[3] 龙孟秋,入选2011年度“中南大学升华猎英学者计划”;

[4] 龙孟秋,湖南大学“优秀博士毕业论文”,2009年。

[5] 陈克求,王玲玲,龙孟秋等,“纳米尺度体系量子输运机理与量子器件计算设计”,湖南省自然科学二等奖,2016年;