1、基本情況

盧卯旺，男，湖南江永人，中國科學院博士（2003），物理學科教授（2003），研究生導師。高校省級青年骨幹教師（1998），高校省級學科帶頭人（2005），廣西首屆自然科學基金委專家委員（2010），校級拔尖人才（2010）。美國AIP、英國IOP、荷蘭Elsevier等出版社專業學術期刊審稿人。在Physical Review B、Applied Physics Letters、IEEE Transactions on Electron Devices等國際主流學術期刊上發表SCI收錄研究論文60餘篇。主持國家自然科學基金3項，中國博士後基金1項、省自然科學基金3項、省教育廳優秀青年科研基金1項。獲廣西自然科學獎三等獎（2017）。
通信地址：廣西桂林市建幹路12号，9728太阳集团首页理學院（郵編：541004）
聯系電話：0773－5896179
Email地址：maowanglu@126.com

2、個人主要經曆

• 2010.01～至今9728太阳集团首页理學院任教

• 2006.04～2009.12南京航空航天大學理學院博士後、任教

• 2003.07～2006.03湘潭大學材料與光電物理學院任教

• 2000.09～2003.06中國科學院固體物理研究所凝聚态物理專業研究生/博士

• 1997.07～2000.08湖南科技學院物理與電子工程系任教

• 1994.09～1997.06湖南師範大學物理研究所天體物理專業研究生/碩士

• 1987.07～1994.08湖南科技學院物理與電子工程系任教

• 1983.09～1987.06湖南師範大學物理學專業本科/學士

3、主要榮譽獎勵

• 廣西自然科學獎三等獎，排名第一

• 湖南省普通高等學校學科帶頭人

• 湖南省普通高等學校青年骨幹教師

• 首屆廣西自然科學基金委專家委員

• 中國科學院優秀博士生

• 9728太阳集团首页拔尖人才

4、教學工作與科研工作

主教：《量子力學》、《計算物理》、《高等量子力學》、《納米電子學》等本科生和研究生課程。

研究：半導體自旋電子學；低維半導體納米結構中量子效應及其調控；低維半導體納米結構電、熱、光輸運；新型量子、納米電子器件的設計與開發

5、主要科研項目

1. 半導體磁量子微結構中傳輸時間與電子自旋極化研究，國家自然科學基金（11864009），46.0萬元，2019-2022，（在研）

2. 磁受限半導體異質結構中δ-摻雜與量子調控研究，國家自然科學基金（61464004），46.0萬元，2015-2018，（在研）

3. 磁調制半導體納米結構中Goos-Hänchen效應與電子自旋極化研究，國家自然科學基金（11164006），58.0萬元，2012-2015，（已結題）

4. 自旋-軌道耦合調制下磁納米結構中電子自旋過濾及其調控研究，廣西自然科學基金（2016GXNSFAA380095），5.0萬元，2016-2018，（在研）

5. Delta摻雜磁調制半導體納米結構及其體系中電子自旋極化效應，廣西自然科學基金（2012GXNSFAA053005），5.0萬元，2012-2015，（已結題）

6. 基于磁調制半導體納米結構的電子自旋過濾器，中國博士後科學基金（2005037216），2.0萬元，2005-2007，（已結題）

7. 磁調節半導體納米結構中的巨磁阻效應，湖南省教育廳優先青年基金（04B053），4.0萬元，2005-2007，（已結題）

8. 磁調節半導體納米結構中電子自旋極化效應，湖南省自然科學基金（04JJ3073），2.0萬元，2004-2006，（已結題）

6、發表的科研論文

1. Mao-Wang Lu^∗, Sai-Yan Chen, Gui-Lian Zhang, Xin-Hong Huang, Spin filter based on magnetically confined and spin-orbit coupled GaAs/Al_xGa_1-xAs heterostructure,IEEE Transactions on Electron Devices, 85 (2018) 304(IF=2.620)

2. Mao-Wang Lu^∗, Sai-Yan Chen, Gui-Lian Zhang, Xin-Hong Huang, Calculations of spin-polarized Goos-Hänchen displacement in magnetically confined GaAs/Al_xGa_1-xAs nanostructure modulated by spin-orbit couplings,Journal of Physics: Condensed Matter, 30 (2018) 14530(SCI,IF=2.617)

3. Mao-Wang Lu^∗, Sai-Yan Chen, Xin-Hong Huang, Gui-Lian Zhang, Spin splitter based on magnetically confined semiconductor microstructure modulated by spin-orbit coupling,IEEE Journal of The Electron Devices Society, 6 (2018) 22(IF=2.696)

4. Mao-Wang Lu^∗, Sai-Yan Chen, Gui-Lian Zhang, Controllable momentum filter based on a magnetically confined semiconductor heterostructure with a δ-doping,IEEE Transactions on Electron Devices, 64 (2017) 182(IF=2.620)

5. Mao-Wang Lu^∗, Xue-Li Cao, Xin-Hong Huang, Ya-Qing Jiang, Shi-Peng Yang, Controllable giant magnetoresistance effect by the δ-doping in a magnetically confined semiconductor heterostructure,Applied Surface Science, 360 (2016) 98(IF=3.387)

6. Mao-Wang Lu^∗, Xue-Li Cao, Xin-Hong Huang, Ya-Qing Jiang, Shuai Li, Shi-Peng Yang, Tunable spin spatial splitter based on a δ-doped realistic magnetic-barrier nanostructure,Superlattices and Microstructures, 77 (2015) 23(IF=2.117)

7. Mao-Wang Lu, Xue-Li Cao, Xin-Hong Huang, Ya-Qing Jiang, Shuai Li, Structurally controllable spin spatial splitter in a hybrid ferromagnet and semiconductor nanostructure,Journal of Applied Physics, 115 (2014) 17430(IF=2.183)

8. Mao-Wang Lu^∗, Zhi-Yong Wang, Yu-Li Liang, Li-Qiong Li, Structurally manipulating electron-spin polarization via δ-doping in a magnetic nanostructure,Applied Physics Letters,102 (2013) 02241(IF=3.515)

9. Mao-Wang Lu^∗, Zhi-Yong Wang, Yu-Li Liang, Li-Qiong Li, Controllable electron-spin polarization by δ-doping in a hybrid ferromagnet and semiconductor nanostructure,EPL, 101 (2013) 4700(IF=2.269)

10. Mao-Wang Lu^∗, Zhi-Yong Wang, Sai-Yan Chen, Gui-Lian Zhang, Voltage -controllable spin beam splitter based on realistic magnetic-barrier nanostructure,Micron, 45 (2013) 1(IF=2.062)

11. Mao-Wang Lu^∗, Zhi-Yong Wang, Xue-Li Cao, Shuai Li, Tunable spin-polarized source by theδ-doping in anisomerous double δ-magnetic-barrier nanostructures,Solid State Communications,165 (2013) 4(IF=1.698）

12. Mao-Wang Lu^∗, Gui-Lian Zhang, Sai-Yan Chen, Spin-electron beam splitters based on magnetic barrier nanostructures,Journal of Applied Physics, 112 (2012) 01430(IF=2.210)

13. Mao-Wang Lu^∗, Xin-Hong Huang, Gui-Lian Zhang, Sai-Yan Chen, Spin beam splitter based on Goos-Hanchen shifts in two-dimensional electron gas modulated by ferromagnetic andSchottky metal stripes,Physica Status Solidi B,249 (2012) 227(IF=1.489)

14. Mao-Wang Lu^∗, Shao-Ming Zhou,A bias-tunable electron-spin filter based on a hybrid ferromagnetic-Schottky-metal and semiconductor nanostructure,Physics Letters A.374 (2010) 4348.（IF=1.963）

15. Mao-Wang Lu^∗, Sai-Yan Chen, Jian-Rong Xiao, Size- and voltage-dependent spin polarization in hybrid ferromagnetic-Schottky-metal and semiconductor nanostructure,Solid State Communications,150 (2010) 1409.（IF=1.981）

16. Mao-Wang Lu^∗, Gui-Lian Zhang, Sai-Yan Chen, A GMR device based on hybird ferromagnetic-Schottky-metal semiconductor nanostructure,Semiconductor Science and Technology, 23 (2008) 035022.（IF=1.434）

17. Mao-Wang Lu^∗,Electron-spin polarization in anti-parallel double δ-magnetic-barrier nanostructure,Applied Surface Science, 252 (3), 1747-1753, 200（IF=1.263）

18. Mao-Wang Lu^∗and Li-De Zhang, Large magnetoresistance tunneling through a magnetically modulated nanostructure,Journal of Physics: Condensed Matter,15 (2003) 1267.（IF=1.757）

19. Mao-Wang Lu^∗, Li-De Zhang, and Xiao-Hong Yan, Electron transport in both magnetically and electrically modulated nanostructures,Nanotechnology, 14 (2003) 609.（IF=2.304）

20. Mao-Wang Lu^∗, Li-De Zhang, Xiao-Hong Yan, Spin polarization of electrons tunneling through magnetic-barrier nanostructures,Physical Review B66 (2002) 22441(IF=3.327)

7、指導研究生發表的論文

1. Qiang Tang(湯強),Mao-Wang Lu^*, Xin-Hong Huang, Yong-Long Zhou, Lateral shifts for spin electrons in a hybrid magnetic-electric-barrier nanostructure modulated by spin-orbit couplings,Journal of Superconductivity and Novel Magnetism, 31 (2018) 138(SCI)

2. Qiang Tang(湯強),Mao-Wang Lu^*, Xin-Hong Huang, Yong-Long Zhou, Controllable spatial spin splitter in an antiparallel double δ-magnetic-barrier semiconductor nanostructure with spin-orbit couplings,Journal of Nonoelectronics and Optoelectronics, 13 (2018) 13(SCI)

3. Shi-Peng Yang(楊士鵬),Mao-Wang Lu^*, Xin-Hong Huang, Qiang Tang, Yong-Long Zhou, Effect of Rashba and Dresselhaus spin-orbit couplings on electron spin polarization in a hybrid magnetic-electric-barrier nanostructure,Journal of Electronic Materials, 46 (2017) 193(SCI)

4. Shi-Peng Yang(楊士鵬),Mao-Wang Lu^*, Xin-Hong Huang, Qiang Tang, Yong-Long Zhou, Effect of Rashba and Dresselhaus spin-orbit couplings on electron-spin polarization in a magnetic-barrier nanostructure,Journal of Nonoelectronics and Optoelectronics, 12 (2017) 63(SCI)

5. Ya-Qing Jiang(蔣亞清),Mao-Wang Lu^*, Xin-Hong Huang, Shi-Peng Yang, Qiang Tang, Manipulable GMR effect inδ-doped magnetically confined semiconductor heterostructure,Journal of Electronic Materials, 45 (2016) 279(SCI)

6. Ya-Qing Jiang(蔣亞清),Mao-Wang Lu^*, Xin-Hong Huang, Shi-Peng Yang, Qiang Tang, Controllable magnetoresistance device based on a δ-doped magnetic nanostructure,Journal of Nonoelectronics and Optoelectronics, 11 (2016) 52(SCI)

7. Shuai Li(李帥),Mao-Wang Lu^*, Ya-Qing Jiang, Sai-Yan Chen, Spin-polarized transport in a δ-doped magnetic-barrier nanostructure,Physics Letters A. 378 (2014) 3189.（SCI）

8. Shuai Li(李帥),Mao-Wang Lu^*, Ya-Qing, Jiang, Sai-Yan Chen, Spin filteringin aδ-doped magnetic-electric-barrier nanostructure,AIP Advances, 4 (2014) 09711（SCI）

9. Sai-Yan Chen（陳賽豔）,Mao-Wang Lu^∗, Yi Tang, Gui-Lian Zhang,Bias-tunable electron-spin polarization in hybrid ferromagnetic-schottky-stripe and semiconductor nanostructure,Modern Physics Letters B, 24 (2010) 106（SCI）

10. Gui-Lian Zhang（張桂蓮）,Mao-Wang Lu^∗, Yi Tang, Sai-Yan Chen,Giant magnetoresistance effect realized by depositing nanosized ferromagnetic and Schottky stripes on a semiconductor heterostructure,Journal of Physics: Condensed Matter.20 (2008) 335221.（SCI）

11. Yong-Hong Kong（孔永紅）,Mao-Wang Lu^∗,Wei-Hua Tang, Chun-Shu Li, Gui-Lian Zhang，Giant magnetoresistance effect in hybrid ferromagnetic/ semiconductor nanosystems，Solid State Communications, 142（2007）14（SCI）