骆军委

  骆军委,男,博士,研究员,博士生导师。 

  2013年入第五批青年千人”,计算材料和器件课题组组长。2006年毕业于中国科学院半导体研究所,获得理学博士学位,导师为深院士;20071月至200911月美国可再生能源国家实验室从事博士后研究,导师为著名物理学家Alex Zunger教授200911月至20141月美国可再生能源国家实验室永久职位研究员;2013年入选中组部第五批青年千人”;20142月进入中国科学院半导体研究所半导体超晶格国家重点实验室工作,组建了从事光电信息功能材料和新能源材料的计和器件性能预测的研究组。 

  在半体自旋-合效绝缘体和米材料等前沿域中取得了一系列新性研究成果:(1了世界上第一个可用来模含有千万个原子的米尺度晶体管的全量子力学三程序(2)在理上卓有成效地广泛研究了半体量子点量子线和量子光学和激子等性,基于半米材料的新一代信息技提供理;(3揭示和解了半体材料量子和量子线等系中新奇的自旋-合效世界上首次有反演称中心的材料中存在藏的自旋化效;(4用反向inverse design方法了高光效率的准直接Si/Ge 超晶格和 Si/Ge core-shell量子线;(5首次在拓绝缘体中现轨道波函数在Dirac点正交切揭露了的二绝缘体的正带图和提出了有效绝缘体材料的方法(6)量子点太池的可行性做了系研究得国同行的广泛 

  40余篇包括Nature Materials 一篇 Nature Physics Nature Communications一篇PRL四篇Nano Letters五篇IF大于10文三篇和若干PRB/APL撰写著三章在国上做邀告五次 

  研究工作经历 

  · 2014/02 - 至今,中科院半导体研究所,半导体超晶格国家重点实验室,研究员 

  · 2014/02 - 至今,教育部2011计划量子信息与量子科技前沿协同创新中心,骨干成员 

  · 2013/11 - 2014/02,美国可再生能源国家实验室,senior scientist 

  · 2009/11 - 2013/11,美国可再生能源国家实验室,staff scientist 

  · 2007/01 - 2009/11,美国可再生能源国家实验室,博士后 

  受教育经历 

  · 2003/03 - 2007/03, 中国科学院半导体研究所, 博士 

  · 2000/09 - 2003/03,浙江大学,物理系,硕士 

  · 1996/09 - 2000/07,浙江大学,物理系,学士 

  主要研究领域方向: 

  1. 半导体低维量子结构的电子性质和激子物理及量子调控 

  2. 半导体信息功能材料的预言、设计和器件模拟 

  3. 半导体新能源材料的理论预言和逆向设计 

  联系方式: 

  E-mailjwluo@semi.ac.cn;电话:010-82304019 

  北京市海淀区清华东路甲35号半导体所超晶格室(2号楼502A室) 

  在研/完成项目: 

  1. 中组部青年千人计划2015/01 – 2017/12,主持 

  2. 自然科学基金委面上项目量子点中重空穴-轻空穴耦合和发光极化各向异性机制和量子调控2015/01 – 2018/12,主持 

  3. 美国能源部推进电池效率基础项目(F-PACE IIOvercoming the fundamental bottlenecks to a new world-record silicon solar cell2014-2017年,350万美元,主研 

  4. 美国科学基金会材料革命与塑造我们的未來(DMREF)计划Theory-guided experimental search of new classes of designed, next-generation wide gap, light element topological insulators2014-2017年,120万美元,主研 

  5. 美国能源部核心项目之Electronic Structure and Fundamental Physics of Semiconductor Nanostructures, 2014-2017年,65万美元,主研 

  6. 美国可再生能源国家实验室LDRD项目Epitaxial ZnSiP2/Si for Tandem Solar Cells,2014-2016,50万美元,主研 

  7. 美国能源部能源前沿研究中心之逆向设计中心 (EFRC-CID)2009-2014年,2千万美元,主研 

  8. 美国能源部下一代硅太阳能电池核心项目,2012-2015年,900万美元,负责理论研究; 

  9. 美国能源部锑基量子点中间带太阳能电池项目,2011-1015年,150万美元,共同主持(co-PI 

  10. 美国能源部量子点太阳能电池理论种子项目,20010-2011年,20万美元,主研 

  11. 美国能源部硅量子点太阳能电池种子项目,2007-2010年,90万美元,主研 

  代表性论著(通讯作者以*标出): 

  [1] Jun-Wei Luo, G. Bester, A. Zunger, “Supercoupling between heavy-hole and light-hole states in self-assembled quantum dots”, Submitted to Phys. Rev. Lett. 

  [2] J. Wang, Jun-Wei Luo, L. Zhang, A. Zunger, “Reinterpretation of the Expected Electronic Density of States of Semiconductor Nanowires”, Nano Letters 15, 88 (2015). 

  [3] X.W. Zhang, Q.H. Liu, Jun-Wei Luo*, A. Freeman, and Alex Zunger*, “Hidden spin polarization in inversion-symmetric bulk crystals”, Nature Physics 10, 387 (2014). 

  [4] J. Ma, H.X. Deng, Jun-Wei Luo, S.H. Wei, "Origin of the failed ensemble averaged rule for the band gaps of the disordered nonisovalent semiconductor alloys", Phys. Rev. B 90, 115201 (2014). 

  [5] M. Gong*, B. Hofer, E. Zallo, R. Trotta, Jun-Wei Luo*, A. Zunger, O.G. Schmidt, C. Zhang, "Statistical Properties of Exciton Fine Structure Splittings and Polarization Angles in Quantum Dot Ensembles", Phys. Rev. B 89, 205312 (2014). 

  [6] L. Zhang, Jun-Wei Luo, A. Saraiva, B. Koiller, and Alex Zunger, “Genetic design of enhanced valley splitting towards a spin qubit in silicon”, Nature Communications 4, 2396 (2013), doi:10.1038. 

  [7] Y. Cao, J.A. Waugh, X.-W. Zhang, Jun-Wei Luo, Q. Wang, T.J. Reber, S.K. Mo, Z. Xu, A. Yang, J. Schneeloch, G. Gu, M. Brahlek, N. Bansal, S. Oh, A. Zunger, and D.S. Dessau, “Mapping the orbital wavefunction of the surface states in three-dimensional topological insulators”, Nature Physics 9, 499504 (2013). 

  [8] M. Heiss, Y. Fontana, A. Gustafsson, G. Wst, C. Magen, D.D. ORegan, Jun-Wei Luo, et al., “Self-assembled quantum dots in a nanowire system for quantum photonics”, Nature Materials 12, 439444 (2013). 

  [9] B.P. Fingerhut, M. Richter, Jun-Wei Luo, A. Zunger, and S. Mukamel, “2D optical photon echo spec-troscopy of a self-assembled quantum dot”, Annalen der Physik 525, 31-42 (2013). 

  [10] B.P. Fingerhut, M. Richter, Jun-Wei Luo, A. Zunger, and S. Mukamel, “Dissecting biexciton wave functions of self-assembled quantum dots by double-quantum-coherence optical spectroscopy”, Physical Review B 86, 235303 (2012). 

  [11] Jun-Wei Luo*, R. Singh, A. Zunger, and G. Bester, “Influence of the atomic-scale structure on the exciton fine-structure splitting in InGaAs and GaAs quantum dots in a vertical electric field”, Physical Review B (Rapid. Comm.) 86, 161302 (2012). 

  [12] L. Zhang, Z. Lin, Jun-Wei Luo, A. Franceschetti, “The Birth of a Type-II Nanostructure: Carrier Localization and Optical Properties of Isoelectronically Doped CdSe: Te Nanocrystals”, ACS nano 6, 8325 (2012). 

  [13] J. Vidal, X. Zhang, V. Stevanovic, Jun-Wei Luo, A. Zunger, “Large insulating gap in topological insulators induced by negative spin-orbit splitting”, Physical Review B 86, 075316 (2012). 

  [14] B.G. Lee, D. Hiller, Jun-Wei Luo, O.E. Semonin, M.C. Beard, M. Zacharias, and P. Stradins, “Strained Interface Defects in Silicon Nanocrystals”, Advanced Functional Materials 22, 3223-3232 (2012). 

  [15] L. Zhang, M. dAvezac, Jun-Wei Luo, A. Zunger “Genomic design of strong direct-gap optical transition in Si/Ge core/multishell nanowires”, Nano letters 12, 984 (2012). 

  [16] Mayeul dAvezac, Jun-Wei Luo, T. Chanier, and Alex Zunger, “Genetic engineering of a direct-gap and optically-allowed superstructure from indirect-gap Si and Ge materials,  Phys. Rev. Lett. 108, 027401 (2012). 

  [17] Jun-Wei Luo and Alex Zunger, “Geometry of epitaxial GaAs/(Al, Ga) As quantum dots as seen by excitonic spectroscopy”, Physical Review B 84, 235317 (2012). 

  [18] Jun-Wei Luo, Lijun Zhang, and Alex Zunger, “Absence of intrinsic spin splitting in 1D quantum wires of tetrahedral semiconductors”, Phys. Rev. B (Rapid. Comm.) 84 121303 (2011). 

  [19] Lijun Zhang, Jun-Wei Luo, Alberto Franceschetti, and Alex Zunger, “Excitons and excitonic fine structures in Si nanowires: Prediction of an electronic state crossover with diameter changes”, Phys. Rev. B 84, 075404 (2011). 

  [20] J. Vidal, X. Zhang, L. Yu, Jun-Wei Luo, and A. Zunger, “False-positive and false-negative assignments of topological insulators in density functional theory and hybrids ”, Phys. Rev. B (Rapid. Comm.) 84, 041109 (2011). 

  [21] Jun-Wei Luo, Paul Stradins, and Alex Zunger, “Matrix-embedded silicon quantum dots for photovoltaic applications: a theoretical study of critical factors”, Energy Environ. Sci. 4, 2546 (2011). 

  [22] Jun-Wei Luo and Alex Zunger, “Design Principles and Coupling Mechanisms in the 2D Quantum Well Topological Insulator HgTe/CdTe”, Phys. Rev. Lett. 105, 176805 (2010). 

  [23] Lijun Zhang, Jun-Wei Luo, Alex Zunger, Nika Akopian, Val Zwiller, and Jean-Christophe Harmand, “Wide InP Nanowires with Wurtzite/Zincblende Superlattice Segments Are Type-II whereas Narrower Nanowires Become Type-I: An Atomistic Pseudopotential Calculation”, Nano Lett. 10, 4055 (2010). 

  [24] Jun-Wei Luo, A. N. Chantis, M. van Schilfgaarde, G. Bester, and A. Zunger, “Discovery of a Novel Linear-in-k Spin Splitting for Holes in the 2D GaAs/AlAs System”, Phys. Rev. Lett. 104, 066405 (2010). 

  [25]  Jun-Wei Luo, Alberto Franceschetti, and Alex Zunger, “Direct-Bandgap InAs Quantum-Dots Have Long-Range Electron-Hole Exchange whereas Indirect Gap Si Dots Have Short-Range Exchange”, Nano Lett. 9, 2648 (2009). 

  [26] Jun-Wei Luo, Alberto Franceschetti, and Alex Zunger, “Nonmonotonic size dependence of the dark/bright exciton splitting in GaAs nanocrystals”, Phys. Rev. B. (Rapid. Comm.) 79, 201301(R) (2009). 

  [27] Franceschetti, J. W. Luo, J. M. An, and A. Zunger, ”Origin of one-photon and two-photon optical transitions in PbSe nanocrystals”, Phys. Rev. B (Rapid. Comm.) 79, 241311 (R) (2009). 

  [28] Jun-Wei Luo, Gabriel Bester, and Alex Zunger, ”Long- and short-range electron-hole exchange interaction in different types of quantum dots”, New J. Phys. 11, 123024 (2009). 

  [29] Jun-Wei Luo, Gabriel Bester, and Alex Zunger, “Full-zone spin-splitting for electrons and holes in bulk GaAs and GaSb”, Phys. Rev. Lett. 102, 056405 (2009). 

  [30] Jun-Wei Luo, Gabriel Bester, and Alex Zunger, ”Atomistic pseudopotential calculations of thickness-fluctuation GaAs quantum dots”, Phys. Rev. B 79, 125329 (2009). 

  [31] Xiang-Wei Jiang, Hui-Xiong Deng, Shu-Shen Li, Jun-Wei Luo, and Lin-WangWang, Quantum mechanical simulation of nanosized metal-oxide semiconductor field-effect transistor using empirical pseudopotentials: A comparison for charge density occupation methods“, J. Appl. Phys. 106, 084510 (2009). 

  [32] Jun-Wei Luo, Alberto Franceschetti, and Alex Zunger, “Carrier Multiplication in Semiconductor Nanocrystals: Theoretical Screening of Candidate Materials Based on Band-Structure Effects”, Nano Lett. 8, 3174 (2008). 

  [33] Jun-Wei Luo, Alberto Franceschetti, and Alex Zunger, “Quantum-size-induced electronic transitions in quantum dots: Indirect band-gap GaAs”, Phys. Rev. B 78, 035306 (2008). 

  [34] Xiu-Wen Zhang, Qiang Xu, Wei-Jun Fan, Jun-Wei Luo, Shu-Shen Li, and Jian-Bai Xia, ”Rashba spin splitting of the minibands of coupled InAs/GaAs pyramid quantum dots”, Appl. Phys. Lett. 92, 143113 (2008). 

  [35] Hui-Xiong Deng, Xiang-Wei Jiang, Jun-Wei Luo, Shu-Shen Li, Jian-Bai Xia, and Lin-Wang Wang, “Multiple valley couplings in nanometer Si metal-oxide-semiconductor field-effect transistors”, J. Appl. Phys. 103, 124507 (2008). 

  [36] Xiang-Wei Jiang, Hui-Xiong Deng, Jun-Wei Luo, Shu-Shen Li, Jian-Bai Xia, and Lin-Wang Wang, “A Fully Three-Dimensional Atomistic Quantum Mechanical Study on Random Dopant-Induced Effects in 25-nm MOSFETs”, IEEE Trans. Electron Devices 55, 1720 (2008). 

  [37] Qiang Xu, Jun-Wei Luo, Shu-Shen Li, Jian-Bai Xia, Jingbo Li and Su-Huai Wei, “Chemical trends of defect formation in Si quantum dots: The case of group-III and group-V dopants”, Phys. Rev. B 75, 235304 (2007). 

  [38] Jun-Wei Luo, Shu-Shen Li, Jian-Bai Xia, and Lin-WangWang, “Quantum mechanical effects in nanometer field effect transistors”, App. Phys. Lett. 90, 143108 (2007). 

  [39] Jun-Wei Luo, Shu-Shen Li, Jian-Bai Xia, and Lin-Wang Wang, “Comparative study for colloidal quantum dot conduction band state calculations”, App. Phys. Lett. 88, 143108 (2006). 

  [40] Jun-Wei Luo, Shu-Shen Li, Jian-Bai Xia, and Lin-Wang Wang, “Photoluminescence pressure coefficients of InAs/GaAs quantum dots”, Phys. Rev. B 71, 245315 (2005). 

  出版专著章节: 

  [1] Jun-Wei Luo*, G. Bester, A. Zunger, "Atomistic Pseudopotential Theory of Droplet Epitaxial GaAs/AlGaAs Quantum Dots", in Nanodroplets edited by Z.M. Wang, (Springer New York, 2013), p.329-361. 

  [2] 骆军委,李深,“太阳能替代传统能源可行?”, 10000个科学难题物理学卷, 科学出版社, 2009, p. 480. 

  [3] 骆军,李深,“晶体管会停止?,10000个科学难题物理学卷, 科学出版社, 2009, p. 521. 

  国际会议邀请报告: 

  [1] Jun-Wei Luo, “Theoretical insight into Silicon quantum dots for solar cell applications”, BIT's 4th New Energy Forum 2014, Sep. 21-23, 2014, Qingdao, China. 

  [2] Jun-Wei Luo, Co-chair of Session 104: Master the Best Solar Technologies, Sep. 21-23, 2014, Qingdao, China. 

  [3] Jun-Wei Luo, “Discovery of supercoupling for heavy-hole and light-hole mixing in self-assembled quantum dots”, The 2014 International Conference on Superlattices, Nanostructures and Nanodevices on Aug. 3-8, 2014, Savannah, Georgia, USA. 

  [4 Jun-Wei Luo, The 248th American Chemical Society National Meeting on Aug. 10-14, 2014, San Francisco, California, USA. 

  [5] Jun-Wei Luo, Chair of Focus Session: Defects in Semiconductors: Nano Materials, APS March Meeting 2014, Denver, USA. 

  [6] Jun-Wei Luo, The 13th International Conference on Condensed Matter Theory and Computational Materials Science, July 13-16, 2014, Chengdu Sichuan, China 

  [7] Jun-Wei Luo, Inverse Design of Si Nanomaterials for Optoelectronic Applications, 2013 JSAP-MRS Joint Symposia, Sep. 16-20, 2013, Kyoto, Japan. 

  [8] Jun-Wei Luo, International Symposium on Nanostructures and Their Applications in Renewable Energy, Oct. 24-27, 2013, Beijing, China. 



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