江建軍(博士生導師):人物經歷,學術研究興趣,學習工作經歷,

人物經歷

教授，博士，博士生導師

華中科技大學光學與電子信息學院，副院長

智慧型電子學研究所，所長國家創新人才培養實驗區——計算材料科學與測量模擬中心，主任

學術研究興趣

（1）射頻和微波電子學——有源頻率選擇表面（AFSS），智慧型算法與智慧型控制器系統設計，雷達信號處理及壓縮感知理論及其FPGA套用。

（2）微波吸收劑——薄膜微波磁學；磁性微波吸收劑電磁參量測量技術。（3）能量電子學——貯能電化學及其電化學超級電容器套用；電化學超級電容器合成製造與測量技術、超級電容器電化學貯能機理的第一性原理與分子動力學計算和新體系計算與設計；柔性超微電容器設計與製造；大型化高比功率雙極結構設計與集成套用。

（4）納米電子學——石墨烯電子學與計算納電子學；第一性原理理論與電子結構計算。

江建軍教授，1995年畢業於浙江大學，獲得博士學位。2004年入選首批“教育部新世紀優秀人才計畫”(批准號：NCET-04-0702)，為湖北省傑出青年基金獲得者。目前學術研究主要集中在有源頻率選擇表面、微波吸收材料製備與系統套用研究和貯能電化學與超級電容器系統的新能源研究領域。已發表學術研究論文160餘篇，SCI收錄100餘篇，編著出版教材3本。目前已完成國家自然科學基金3項、教育部新世紀優秀人才基金項目、湖北省傑出青年基金、留學回國人員基金等國家級科研項目20餘項。

在承擔繁重國家科研項目同時，從2000年回國以來，江建軍教授長期工作在教育、教學工作第一線，特別重視面向群體的本科教學創新研究與改革實踐，已連續三屆獲得省級教學成果獎一等獎及一屆國家級教學成果二等獎。“計算材料學與新材料設計跨學科虛擬基地建設”通過省級鑑定，2005年獲得湖北省高等學校教學成果一等獎(排名第一)。2007年獲得華中科技大學第二屆“教學名師”稱號，並全面負責“面向群體創新人才互動式培養實驗區”國家人才培養模式創新實驗區的建設工作。2009年“理工科本科生研究性教學改革和實踐模式”，獲得湖北省省級教學成果獎一等獎及國家教學成果獎二等獎（排名第三）。主講的《計算材料學與材料設計基礎》2010年獲得省級精品課程。結合不斷推進理論和實踐教學改革，所獲系列成果成效顯著，形成“基於課程、面向群體、學術創新、交叉融合、實踐育人”的創新特色。2013年“面向群體創新學習共同體的課程教學範式和實踐方法”獲得湖北省教學成果獎一等獎（排名第一），並推薦國家教學成果獎入圍評獎資格。

從一門專業核心課程建設出發，他開展了連續13年教育教學改革實踐探索，探索了面向大班面上教學的創新教育模式，構建學習共同體的課程教學範式和實踐方法，營造人文情懷根植於課程素質教育環節和以學生為中心的教育創新環境，促進終身學習能力，很好地解決了大班教學中制約群體創新實踐教育的瓶頸。系列教育教學成果具有引領和示範推廣效果，已套用於指導我光電信息國家試點學院18門主幹課程建設，通過建設精品課程、編著出版理論和實踐結合的特色教材和建成面向群體創新人才互動式培養國家人才模式創新實驗區基地，有多家媒體廣泛報導，起到了良好的示範輻射作用。

學習工作經歷

1.學術研究經歷

2012/06-至今，華中科技大學，光學與電子信息學院，副院長，教授；

2003/04-2012/06，華中科技大學，電子科學與技術系，副系主任，教授；

2001/06-2003/03，華中科技大學，電子科學與技術系，教授；

2000/03-2001/06，華中科技大學，電子科學與技術系，副教授。

1991/09-1995/05，浙江大學材料科學與工程系，攻讀博士學位。

2.海外訪學經歷

1999/03-2000/02，荷蘭赫爾辛基工業大學（HUT），高級訪問學者，主要研究高性能氫化物半燃料電池研究；

1998/09-1999/03，Technion以色列工學院（Technion-IIT），博士後，主要開展鐵基電池用納米材料研究；

1997/10-1998/09，韓國先進技術研究院（KAIST），博士後，從事高性能鎂基貯氫電極合金機械合金化製備研究；

3.科研學術榮譽

2004年入選首批“教育部新世紀優秀人才計畫” (批准號：NCET-04-0702)，為湖北省傑出青年基金獲得者。目前已完成國家自然科學基金項目3項，新世紀優秀人才基金，留學回國人員基金等。目前在研項目國家自然科學基金等。發表學術論文160餘篇，其中SCI收錄110餘篇。

近五年主持負責的重要研究項目：

（1）國家基金科學基金2012-2015年，項目負責人

（2）國家自然科學基金項目“納米顆粒膜微波介電損耗調控機理研究”，2009-2011，項目負責人；

4.教學學術榮譽

2013年"面向群體創新學習共同體的課程教學範式和實踐方法"獲得湖北省高等學校教學成果獎一等獎（排名第一）；

2013年華中科技大學教學質量一等獎（全校僅11門課程之一）；

2013年華中科技大學課程設計一等獎；

2012年獲得"寶鋼教育基金優秀教師獎"；

2010年湖北省級精品課程《計算材料學與材料設計基礎》（排名第一）；

2009年"理工科研究性教學的理論與實踐"獲得高等學校教學成果獎省級一等獎和國家級二等獎（排名第三）；

2005年"計算材料學與新材料設計跨學科互動式虛擬基地建設"獲得湖北省高等學校教學成果獎一等獎（排名第一）；

獲得2009－2012年湖北省大學生成果獎一等獎、二等獎和三等獎等指導教師；

獲得2008-2013年期間分別獲得一等獎，二等獎，三等獎等指導教師，湖北省優秀學士論文指導獎導師。

5.學術兼職

學術兼職有中國能源學會常務理事，中國電子學會高級會員，中國稀土學會固體科學與新材料分會委員，中國材料研究學會高級會員，國際氫能協會高級會員，《功能材料》雜誌通訊編委，《電子科技大學學報》中英版編委。國防基礎研究專家，2009年全國百篇優秀論文評審專家，國家自然科學基金評審專家、中小企業創新基金評審專家等。國際SCI雜誌Advanced Materials；Journal of Power Sources；Journal of Alloys and Compounds；Applied Surface Sciences；Journal of Magnetism and Magnetic Materials等，國內SCI期刊《物理學報》《無機材料學報》《金屬學報》《中國科學》《中國有色金屬學報》等特邀審稿人。

6.代表性論著

（1）專著或者教材

[1] 江建軍,劉繼光.《LabVIEW程式設計教程》. 北京：電子工業出版社，49.3萬字，2008年3月，ISBN 978-7-121-05935-3

[2] 江建軍，繆靈，梁培，馬新國. 《計算材料學-設計實踐方法》. 北京: 高等教育出版社，43.9萬字，2010年2月，ISBN 978-7-04-026963-5

[3] 江建軍，孫彪. 《LabVIEW程式設計教程》（第二版）. 北京：電子工業出版社，50萬字，2012年2月，ISBN 978-7-121-15635-9

（2）近年來代表性研究學術論文

2015

1. Chi Chen, Kui Xu, Xiao Ji, Bao Zhang, Ling Miao* and Jianjun Jiang. Enhanced Electrochemical Performance by Facile Oxygen Vacancies from Lower Valence-State Doping for Ramsdellite-MnO2. J. Mater. Chem. A, 3:12461, 2015.

2. Kui Xu, Xiao Ji, Chi Chen, Houzhao Wan, Ling Miao*, Jianjun Jiang. Electrochemical double layer near polar reduced graphene oxide electrode: Insights from molecular dynamic study. Electrochimica Acta, 166:142, 2015.

3. Xiao Ji, Kui Xu, Chi Chen, Bao Zhang, Houzhao Wan, Yunjun Ruan, Ling Miao and Jianjun Jiang*. Different charge-storage mechanisms in Disulfide Vanadium and Vanadium Carbide Monolayer. J. Mater. Chem. A, 3:9909-9914, 2015.

4. Mengyun Zhao, Xiaowei Yu, Qiao Wang, Peng Kong, Yun He, Ling Miao*, Jianjun Jiang. Novel Absorber Based on Pixelated Frequency Selective Surface Using Estimation of Distribution Algorithm. IEEE Antennas and Wireless Propagation Letters, 14: 1467, 2015.

5. Xin Cong, Yiming Liao, Qiji Peng, Yidan Yang, Chuan Cheng, Wenqing Zhang, Peilin Fang, Chi Chen, Ling Miao*, and Jianjun Jiang. Contrastive band gap engineering of strained graphyne nanoribbon with armchair and zigzag edges. RSC Advances, 5:59344, 2015.

6. Xin Cong, Chuan Cheng, Yiming Liao, Yifei Ye, Changxu Dong, He Sun, Xiao Ji, Wenqiang Zhang, Peilin Fang, Ling Miao* and Jianjun Jiang. Intrinsic charge storage capability of Transition Metal Dichalcogenides as Pseudocapacitor electrode, J Physical Chemistry C, 119:20864, 2015.

7. Zhu Lv, Huiyu Mo, Chi Chen*, Xiao Ji, Kui Xu, Ling Miao , Jianjun Jiang. The Effective Adsorption and Decomposition of N2O on Al-decorated Graphene Oxide under Electric Field. RSC Advances, 5:18761-18766, 2015.

8. Haichao Chen, Jianjun Jiang, Yuandong Zhao, Li Zhang, Danqing Guo, Dandan Xia. One-pot Synthesis of Porous Nickel Cobalt Sulphides: Tuning the Composition for Superior Pseudocapacitance. Journal of Materials Chemistry A, 2015, 3, 428–437.

9. Haichao Chen, Jianjun Jiang, Li Zhang, Yuandong Zhao, Danqing Guo, Yunjun Ruan, Dandan Xia. One-Pot Fabrication of Layered α-Phase Nickel–Cobalt Hydroxides as Advanced Electrode Materials for Pseudocapacitors. ChemPlusChem, 2015, 80, 181–187.

10. Dandan Xia, Haichao Chen, Jianjun Jiang, Li Zhang, Yuandong Zhao, Danqing Guo, Jingwen Yu. Facilely Synthesized α Phase Nickel–Cobalt Bimetallic Hydroxides: Tuning the Composition for High Pseudocapacitance. Electrochimica Acta, 2015, 156, 108–114.

11. Houzhao Wan, Jia Liu, Yunjun Ruan, Lin Lv, Lu Peng, Xiao Ji, Ling Miao, and Jianjun Jiang，Hierarchical Configuration of NiCo2S4 Nanotube@Ni–Mn Layered Double Hydroxide Arrays/Three-Dimensional Graphene Sponge as Electrode Materials for High-Capacitance Supercapacitors,ACS Appl. Mater. Interfaces, 2015, 7 (29),15840–15847.

12. Houzhao Wan, Lin Lv, Lu Peng, Yunjun Ruan, Jia Liu, Xiao Ji, Ling Miao, Jianjun Jiang,Hollow spiny shell of porous Ni–Mn oxides: A facile synthesis route and their application as electrode in supercapacitors,Journal of Power Sources, 2015,286(15), 66–72

13. Yunjun Ruan, Jianjun Jiang*, Houzhao Wan, Xiao Ji, Ling Miao, Lu Peng, Bao Zhang, Lin Lv, Jia Liu, Rapid self-assembly of porous square rod-like nickel persulfide via a facile solution method for high-performance supercapacitors, Journal of Power Sources, 2016, 301, 122-130.

14. Lu Peng, Xiao Ji, Houzhao Wan, Yunjun Ruan, Kui Xu, Chi Chen, Ling Miao,Jianjun Jiang*. Nickel Sulfide Nanoparticles Synthesized by Microwave-assisted Method as Promising Supercapacitor Electrodes: An Experimental and Computational Study. Electrochimica Acta，2015, 182, 361-367.

15. Haibing Xu, Shaowei Bie*, Jianjun Jiang, Dong Wan, Jie Zhou and Yongshun Xu. Broadening bandwidth of the composite radar absorption material involving a frequency selective surface. JOURNAL OF ELECTROMAGNETIC WAVES AND APPLICATIONS. 2015, 29, 60-68.

16. Haibing Xu, Shaowei Bie*, Yongshun Xu, Wei Yuan, Qian Chen and Jianjun Jiang. Broad bandwidth of thin composite radar absorbing structures embedded with frequency selective surfaces. Composites Part A: Applied Science and Manufacturing. 2015

17. Haibing Xu, Shaowei Bie*, Jianjun Jiang, Wei Yuan, Qian Chen and Yongshun Xu. Electromagnetic and microwave absorbing properties of the composites containing flaky FeSiAl powders mixed with MnO2in 1-18GHz. Journal of Magnetism and Magnetic Materials. 2015.

18. Yongshun Xu, Wei Yuan, Shaowei Bie*,Haibing Xu, Qian Chen & Jianjun Jiang.Broadband microwave absorption property of a thin metamaterial containing patterned magnetic sheet.JOURNAL OF ELECTROMAGNETIC WAVES AND APPLICATIONS,2015.

19. Wenhua. Xu, Yun. He, Peng. Kong, Jialin. Li, Haibing. Xu, Ling. Miao, Shaowei. Bie and Jianjun. Jiang. An ultra-thin broadband active frequency selective surface absorber for ultrahigh-frequency applications. J APPL PHYS. 2015.

20. Zhimi Hu, Xu Xiao,Chi Chen,Tianqi Li, Liang Huang, Chuanfang Zhang, Jun Su, Ling Miao, Jianjun Jiang, Yanrong Zhang and Jun Zhou*. Al-doped α-MnO2for high mass-loading pseudocapacitor with excellent cycling stability.Nano Energy, 2015, 11, 226–234.

21. C.D. Wang, Y.S. Li, J.J. Jiang, W.-H. Chiang, Controllable tailoring graphene nanoribbons with tunable surface functionalities: an effective strategy towards high performance lithium-ion batteries,ACS Appl. Mater. Interf.,2015, 7,17441–17449.

22. L. Zhang, H. Xia, C. Qiu, J. J. Jiang, S. W. Bie, "Effect of Carrier Gas Flow Rate on In2O3 Nanostructure Morphology and Growth Mechanism", Journal of Nano Research, Vol. 31, pp.117-128, Apr. 2015

2014

1. Chen Haichao, Jiang Jianjun, Zhang Li, Qi Tong, Xia Dandan, Wan Houzhao. Facilely synthesized porous NiCo2O4 flowerlike nanostructure for high-rate supercapacitors. Journal of Power Sources ( IF=5.211 ),248:28, 2014.

2. Chen Haichao, Jiang Jianjun, Zhang Li, Xia Dandan, Zhao Yuandong, Guo Danqing, Qi Tong, Wan Houzhao. In situ growth of NiCo2S4 nanotube arrays on Ni foam for supercapacitors: Maximizing utilization efficiency at high mass loading to achieve ultrahigh areal pseudocapacitance. Journal of Power Sources ( IF=5.211 ),254:249, 2014.

3. Chen Chi, Xu Kui, Ji Xiao, Miao Ling, Jiang Jianjun. Enhanced adsorption of acidic gases (CO2, NO2 and SO2) on light metal decorated graphene oxide. Phys. Chem. Chem. Phys. ( IF= 4.198), 2014, 16:11031

4. Li Yutao, Wang Xiaojie, Shi Wenhao, Yan Zeyu, Zhao Chengbo, Chen Chi, Miao Ling, Jiang Jianjun. Enhanced and adjustable adsorption of organo-functional groups on Li decorated carbon nanotubes: A first principle study. J Applied Physics, 116:084308, 2014

5. Zeyu Yan, Lang Wang, Julong Cheng, Libei Huang, Chao Zhu, Chi Chen, Ling Miao, and Jianjun Jiang. Lithium-decorated oxidized graphyne for hydrogen storage by first principles study. J Applied Physics, 116: 174304, 2014

6. Yu Jingwen, Wan Houzhao, Jiang Jianjun, Ruan Yunjun, Miao Ling. Activation Mechanism Study of Dandelion-Like Co9S8 Nanotubes in Supercapacitors.. Journal of The Electrochemical Society ( IF= 2.859 ),161:A996, 2014.

7. Wan Hou-Zhao, Jiang Jian-Jun,Yu Jing-Wen, Ruan Yun-Jun,Peng Lu, Zhang Li, Chen Hai-Chao, Bie Shao-Wei. Cobalt sulfide nanotube arrays grown on FTO and graphene membranes for high-performance supercapacitor application.. Applied Surface Science, 311: 793–798, 2014. IF=2.538

8. Wan Houzhao, Jiang Jianjun, Ruan Yunjun, Yu Jingwen, Zhang Li, Chen Haichao, Miao Ling, Bie Shaowei. Direct Formation of Hedgehog‐Like Hollow Ni‐Mn Oxides and Sulfides for Supercapacitor Electrodes. Particle & Particle Systems Characterization, 31: 857–862, 2014

9. Peng Kong, XiaoWei Yu, ZhengYang Liu, Kai Zhou, Yun He, Ling Miao, and JianJun Jiang. A novel tunable frequency selective surface absorber with dual-DOF for broadband applications. Optics Express, 2014, 22(24): 30217–30224. IF=3.525

10. Zhang Wuqiang, Bie Shaowei, Chen Haichao, Lu Yao, Jiang Jianjun Electromagnetic and microwave absorption properties of carbonyl iron/MnO2 composite. Journal of Magnetism and Magnetic Materials ( IF=2.002 ),358:1, 2014.

11. Haibing Xu, Shaowei Bie, Jianjun Jiang, Dong Wan, Jie Zhoua &Yongshun Xu Broadening bandwidth of the composite radar absorption material involving a frequency selective surface. Journal of Electromagnetic Waves and Applications,2014

12. Li Chenyang, Miao Ling, Tan Xiaojian, Han Mengdi, Jiang Jianjun. Thermal Conductivity of Graphene Nanoribbons with Regular Isotopic Modification. . Journal of Computational and Theoretical Nanoscience, 11:348, 2014.

13. Peng Kong, Xiao -Wei Yu, Ling Miao, and Jian-Jun Jiang . Switchable Frequency Selective Surfaces Absorber/Reflector for Wideband Applications . In Ultra-WideBand (ICUWB), 2014 IEEE International Conference on. IEEE. Sep., 2014. Paris, France.

14. 徐永順, 別少偉, 江建軍, 徐海兵, 萬東, and 周杰含螺旋單元頻率選擇表面的寬頻帶強吸收複合吸波體. 物理學報, pp. 245-250, 2014-10-23 2014

Prof.& Dr.Jianjun Jiang

Vice Dean of SOEI，SchoolofOpticalandElectronicInformation(SOEI)

Director of IEI，Intelligent Electronics Institute (IEI)

Director of CCMS，Center for Computational Materials Science and Computer Measurement Simulation (CCMS)

Research Interest & Area of Expertise:

Microwave Electronics, Intelligent Eletronics, Energy Electronics, Nanoelectronics

Academics Positions:

Professor & Vice Dean of SOEI, 2012-present

Huazhong University of Science andTechnology,

School of Optical and Electronic Information

Intellignet Electronics Institute

Professor & Vice Director of Department, 2001-2011

Huazhong University of Science andTechnology,

Department of Electronic Science and Technology

Intellignet Electronics Institute

Associate Professor 2008-2000

Huazhong University of Science and Technology,

Center for Automobile Research of Advanced Technology

Postdoctoral Scholar 1997-1998, Department of Materials Science and Engineering, Korea Advanced Institute of Science and Technology (KAIST), South Korea

Postdoctoral Scholar 1998 to 1999, Technion Israel Institute of Technology (Technion-IIT), Haifa, Israel

Senior visiting Scholar, 1999-2000, Helsinki University of Technology, Espoo，Finland

Key Scientific Contributions

[A] Radio Frequency and Microwave Electronics: Theory and Design for Active Frequency Selective Surfaces(AFSS)

Most attention is paid to frequency selective surfaces (FSS).For improving the performance of FSS, intelligence algorithm is used to optimize its parametric model, such as Genetic Algorithm (GA). GA is used to optimize the EM performances of FSS due to its superiority to solve multi-variables optimization problem. By using GA and optimizing the geometry and size of the FSS unit cell as well as the thickness and dielectric constant of the substrate material, it is possible to design multiband artificial magnetic conducting surfaces that work for nearly any desired combination of operating frequencies. However, the traditional GA can not apply to the cases of evaluating polymorphic individual which having opposite performances, such as switchable absorber/reflector. In this case, it has to comprehensively evaluate the performance in ON and OFF state of each individual during the optimization.

We investigate a wideband switchable FSS absorber/reflector. Discussions are carried out around how to integrate broadband absorption and switchable performance into FSS structure. Polymorphic union evaluation genetic algorithm (PUE-GA) is put forward to optimize the parametric model of FSS element and comprehensive evaluate the performances of switchable FSS. The results showed that the switchable absorber/reflector could both have wideband absorption and switchable properties over the C-band frequency range (4–8 GHz), and PUE-GA is able to improve the design of switchable FSS absorber/reflector.

[B] Energy Electronics & Supercapacitors: Scientific Fundamentals of Energy Storage Electrochemistry and Technological Application of Supercapacitors

With the fast-growing energy depletion and environmental degradation, numerous efforts have been made to develop energy storage and conversion from alternative energy sources, such as, lithium ion battery, supercapacitors, fuel cell. Supercapacitors as new energy storage devices, have drawn an increasing attention because they can provide an energy density higher than traditional capacitors, and greater power density and longer cycling ability compared to rechargeable batteries. Binary metal compounds (oxides,hydroxides and sulfides) possessing multiple oxidation states and/or architectures that enable multiple redox reaction activity, have been reported to exhibit a higher performance than single metal components. Most of them seem to be some of the most promising and low cost materials for supercapacitors. For instance, the ultrathin mesoporous NiCo₂O₄ nanosheets on conductive nickel foam exhibit superior pseudocapacitive of 1450 F g, even at a very high current density of 20 A g, and excellent cycling performance at high rates. The Cobalt-nickel layered double hydroxides have a high specific capacitance of 2104 F g. The porous NiCo₂S₄ nanotubes show a specific capacitance of 1093 F g at a current density of 0.2 A g. Up to now, the unitary nickel or manganese compounds have been widely studied for supercapacitors, due to their excellent electrochemical performance, low cost (especially for the material systems with containing a large amount of cobalt) and environmental friendly. However, the synthesis and electrochemical characterization of the binary Ni-Mn compounds (Ni-Mn oxides or Ni-Mn sulfides) are rarely reported, which may exhibit more excellent electrochemical performances than that of the unitary nickel or manganese compounds. Therefore, preparation of binary Ni-Mn oxides or sulfides, and study of their formation mechanism are very usefulfor application-specific supercapacitors.

The development of three-dimensional (3D) micro-nanostructures with one-dimensional (1D) nanostructures as building units can provide a promising solution to enhance the capacitive performance because of their high surface area, short electron and ion transport pathways. Among them, the 3D hollow structures such as, hollow ZnO, Fe₂O₃, CuO, ZnS, with 1D nanoneedle nanostructure in the surface of shell were carried out, especially for application in supercapacitors. However, most of the previous syntheses usually involve the use of hard templates, soft surfactants, toxic organic solvents, and complicated procedures. The resultant structures are largely limited to low-order structures and are not very efficient for practical applications. Therefore, it is essential but challenging to develop a facile, controllableand environmental friendly method to produce binary Ni-Mn compounds of hollow hedgehog-like structures with uniform size ordered 1D nanostructures as high-performance electrode materials for supercapacitor applications. In our work, we report a one-step and novel approach synthesis of hollow hedgehog-like binary Ni-Mn precursor based on directional growth of Mn induced. In the formation process of hollow hedgehog-likestructure, Mn play a very important inducing role which is similar to the growth of the pute hollow manganese dioxide.The plausible formation mechanism of such directional Mn-induced synthesis can be described as shown in Figure 1. The induced mechanism is conducted as follows: (1) In the beginning, the OH formed by urea hydrolysis reacts with Ni and aggregates to form nucleation centre;(2) The nucleation centre subsequently adsorp Mn and form flocculent nanostructures at the surface of nucleation product; (3) After prolonged hydrothermal treatment, the internal of nucleation gradually form hollow structure as the induction process; (4) Finally, the precursor will further be inducted and crystallize into shell and needle-like nanostructures in surface of shell, forming a complete hollow hedgehog-like framework. The hollow hedgehog-like binaryNi-Mn oxides and sulfides are obtained after thermal treatment and vulcanization for hollow hedgehog-like binaryNi-Mn precursor and retain the morphology of the precursor with one-dimensional (1D) nanoneedles as building units. The excellent electrochemicalperformance of hollow hedgehog-like Ni-Mn oxides and sulfides benefit from its unique 3D open structure, effectively buffering the volume strains during the ion electrolyte adsorption/desorption process。

[C] Nanoelctronics: Computational Nanoscale Materials Science and Electronic Structure Analysis by First Principle Calculations

Graphene, which is an exciting two-dimensional material, shows great promise for the fabrication of nanoscale devices with its interesting semimetal electronic properties. And quasi-one-dimensional graphene nanoribbons (GNRs) can generally be either metallic or semiconducting depending on the patterns formed by their edges. What’s more, GNRs sub 10 nm present the excellent semiconducting character because of the quantum confinement effect and edge effect. Thus the ultra-narrow GNRs can be the ideal materials for lots of nanoscale devices. Nowadays, the usual methods to fabricate GNRs are electron-beam lithography and plasma etching, chemical synthesis, and chemical vapor deposition method. Most GNRs fabricated by these ways are difficult to ensure the crystallographic orientation and achieve smooth graphene edges simultaneously during fabrication. And it’s hard to reach the target of sub 10 nm.

The productions have smooth edge and a narrow width distribution (10–20 nm). In this way, the width of GNRs can be well controlled. From then on, the method to fabricate GNRs through unzipping CNT becomes a hot issue. The mechanism of oxygen-driven unzipping of CNT was investigated using density functional theory calculations. Unzipping starts with attacking one of the internal C–C bonds of CNT, then stretching and breaks it. Soon afterwards, many researches were carried on. Also there are other adsorbates to break C-C bond, such as H atom, transition metal, and alloy. Furthermore, kinds of production could be got through this way according to different requirements, such as bilayer GNRs with tunable width, aligned GNR arrays, and magnetoresistive device. Very recently, this method has already been applied into unzipping and cutting of graphene. However, there are also some problems need to explore. The irregular initial adsorption of O adatom and the relatively high energy barrier of O diffusion on CNTs, will go against to ensure smooth edges of GNRs.

On the other hand, the charge transfer and electron redistribution caused by external electric field will apparently affect the physical and chemical properties of nano materials. The effect of electric field on the electronic structure of nano materials, such as single-walled carbon nanotube (SWCNT), boron nitride nanotube, graphene, bilayer graphene, GNRs, has been investigated, and a tunable band gap could be achieved for these materials. In addition, the electron redistribution will change the intensity of atomic interaction and chemical bond. The gases, such as H₂, O₂, N₂O, adsorption on nano materials could be influenced by electric field greatly. Even a reversible reduction and oxidation of graphene oxide was realized by electric field. Furthermore, too large electric field even could break the structure of hydrogenated SWCNT.

In our work, we investigate the effect of electric field on orientation-selective oxygen-driven unzipping of CNT. The relaxed structure of CNT, the binding energies and the diffusion barrier of O adatom at kinds of site on CNT under different electric fields are calculated to study the possibility of longitudinal unzipping SWCNT.

Carbon dioxide, nitrogen dioxide and sulfur dioxide are acidic gaseous pollutants, coming from both natural and industrial procedures, accumulating in the atmosphere, reacting under certain atmospheric conditions, and leading to greenhouse effect, photochemical smog and acid rain, which are great threats to global processes and human health nowadays.

The most efficient way to reducehazards of acidic gases has been proven to be gases capture after the burning of fuels and before the emission of acidic gases. Ammonia scrubbing, denitrification processes and flue gas desulfurization are the traditional methods to control the emission of CO₂, NO₂ and SO₂.However, these processes will be more or less high absorbent and running cost, low removal efficiency, poor absorbent utilization ratio, high secondary pollution, and large occupying area. In this paper, a novel nanomaterial with large specific area, high stability and less contamination, will be studied on the removal of acidic gases.

Graphene, which is an exciting two-dimensional material with many interesting semimetal electronic properties, shows great promise for fabrication of nanoscale devices. And modified graphenes are put forward to avoid its physical native defect while applying in devices, such as graphene oxide (GO), graphene nanoribbons, crumpled graphene, doped graphene, metal decorated graphene and so on. Among them, GO exhibits a moderate conductivity, high chemical stability, and excellent mechanical, optical, thermal, electrochemical properties. Hence, GO is prepared and applied into gas sensor or storage, high-performance fibers, composite membranes, electro-chemical applications, energy devices, field effect transistors and so forth. Here, its outstanding performance in gas storage catches our eyes.

In our work, much more eco-friendly, cheaper and lighter metals (Li, Al) are selected to decorate GO to investigate acidic gases (CO₂, NO₂and SO₂) adsorption effectiveness comparing with transition metal (Ti). High binding energy and oxygen adsorption restraint are the targets. The relaxed structures of pure and metal decorated GO, the binding energies of gases on metal decorated GO and charge transfer are calculated to study the efficient removal of acidic gases.

The adsorption of several acidic gases (CO₂, NO₂ and SO₂) on light metal (Li, Al) decorated graphene oxide (GO) is theoretically studied, based on the first-principle calculations. Configuration relaxation, binding energy and charge transfer are carried out to discuss the acidic gas adsorption ability of light metal decorated GO. It’s found out that Li, Al could be anchored stably by hydroxyl and epoxy groupson GO, and then a strong adsorption will occur of CO₂, NO₂ and SO₂above these light metals. In contrast to Ti, Li decorated GO performs a comparable adsorption ability of acidic gases, but a much smaller interaction with O₂ about 2.85 ~ 3.98 eV lower in binding energy; and Al decorated GO displays much higher binding energy of all acidic gases with enhancement of about 0.59 ~ 2.29 eV.The results of enhanced acidic gas adsorption ability and a reduced interferenceof O₂, imply that Li, Al decorated GO may be useful and promising for collection and filtration of exhaust gases.

Academic Degrees

PhD , 1995, Zhejiang University ,Graduate School, Hangzhou, China

Master, 1991, Wuhan University of Science and Technology, Wuhan, China

BA, 1986, Wuhan University of Science and Technology, Wuhan, China

Selected Scientific Publications

Book edit-in-chief

[1] Jiang Jian-jun (江建軍), Liu Jiguang. LabVIEW Program Design, Beijing: Publishing House of Electronics Industry, (First Edition) 2008, ISBN 978-7-121-05935-3

[2] Jiang Jian-jun，Miao Ling，Liang Pei, Ma Xinguo. Computational Materials Science: from Basic Principle to Practice. Beijing : Higher Education Press，2010，ISBN 978-7-04-026963-5

[3] Jiang Jian-jun (江建軍), Sun Biao. LabVIEW Program Design, Beijing: Publishing House of Electronics Industry, (Second Edition) 2012, ISBN 978-7-121-15635-9

Selected Scientific Papers