教师主页移动版

个人经历 personal experience 工作经历 教育经历 2021.10-今 西北工业大学物理科学与技术学院  教授2019.06-今 西北工业大学物理科学与技术学院  硕士生、博士生导师2015.12-2021.10 西北工业大学物理科学与技术学院  副教授 2014.06-2015.12 澳大利亚斯威本科技大学微光子学中心  博士后 （导师：顾敏院士） 2008.09-2014.01 中国科学院大学获博士学位（硕博连读）

教育教学

教育教学 Education and teaching 教育教学 主讲：《大学物理实验》 本科生课程    《College Physics Experiments》国际班课程          《计算光子学》 研究生课程

荣誉获奖

荣誉获奖 Awards Information 2023年 入选全球前2%顶尖科学家榜单（World’s Top 2% Scientists）2023年 入选爱思唯尔2022中国高被引学者（光学工程）2022年 入选全球前2%顶尖科学家榜单（World’s Top 2% Scientists）2022年 入选爱思唯尔2021中国高被引学者（光学工程）2021年 入选全球前2%顶尖科学家榜单（World’s Top 2% Scientists ）2021年 入选爱思唯尔2020中国高被引学者（光学工程）2020年 第十三届陕西青年科技奖 （两年评选一次）2012年 中国科学院“院长优秀奖”

科学研究

科学研究 Scientific Research 主要研究领域：微纳光子学、等离激元光子学、纳米材料光学 截至2022年10月，在Light: Science & Applications、Laser & Photonics Reviews、Nanoscale、Nanophotonics、Photonics Research、Optics Letters、APL Photonics、Physical Review A 等国内外主流学术期刊上发表第一作者SCI论文30余篇，通讯作者论文10余篇，授权国家发明专利1项。其中，8篇（曾）入选ESI 1%“高被引论文”，1篇被Nanoscale选为内封面论文,1篇被Nanotechnology选为封面故事，2篇入选美国光学学会（Optica）数据库“周图片”，2篇入选编辑精选，3篇进入期刊月下载量“Top 10”。共发表SCI论文100余篇，被引超过6400次（Google Scholar），h因子43。多次参加国际学术会议并作邀请报告（12次），组织分会（3次），担任分会主持人（4次）。主持国家自然科学基金项目3项，省部级项目多项，校级项目多项。获第十三届陕西青年科技奖，2021-2023年连续三次入选爱思唯尔中国高被引学者，2021-2023年连续三次入选全球前2%顶尖科学家榜单（终身影响力）。被邀请为Light、AOM、ACS Photonics、Nanoscale Advances、Nanoscale、Photonics Research、Optics Letters、Optics Express、Europhysics Letters、IEEE Photonics Journal、IEEE Photonics Technology Letters、APL Photonics等30余种国际学术期刊审稿人。 个人学术网页：http://scholar.glgoo.org/citations?hl=zh-CN&user=pwZUrKUAAAAJ&view_op=list_works                        https://www.researchgate.net/profile/Hua_Lu12/info 目前关注的主要研究方向1. 表面等离激元调控、器件与应用2. 光与新型纳米材料相互作用3. 片上微纳光子器件4. 光场的微结构调控主持项目1.国家自然科学基金面上项目2项 （1项已结题）2.国家自然科学基金青年科学基金项目1项（已结题）3.陕西省自然科学基础研究计划面上项目1项（已结题） 4.西北工业大学“翱翔新星”人才计划5.陕西省自然科学基础研究计划青年项目1项 （已结题）6.陕西省留学人员科技活动择优资助项目 1项 （已结题）7.中央高校基本科研业务费项目2项（已结题）8.西北工业大学人才引进启动经费项目1项（已结题） 欢迎具有光学、光电子学、物理学等相关背景的同学报考硕士、博士研究生 [光学工程或光电信息工程]。研究条件：微纳加工（FIB、EBL、ICP、光刻、磁控溅射、ALD、电子束蒸镀等）、表征（SEM、AFM、TEM、XRD等）、测试（共聚焦Raman、微区光谱测试、高分辨波导耦合系统、微区非线性测试系统等）。已与国内外多所高校课题组建立合作关系。指导本科生获得大创项目6项（国家级4项，省级1项）；指导本科生获得院优秀毕业设计论文2篇；指导本科生发表学术论文2篇（学生一作）；指导研究生发表学术论文多篇；指导多名研究生获得西北工业大学优秀毕业生。

学术成果

学术成果 Academic Achievements 发表论文如下: (Selected Publications, *:corresponding author）51. Hua Lu,* Shouhao Shi, Dikun Li, Shuwen Bo, Jianxu Zhao, Dong Mao, and Jianlin Zhao*, “λ/20-thick cavity for mimicking electromagnetically induced transparency at telecommunication wavelengths,” Advanced Photonics 已录用 (2024)  (IF=17.3)50. Chunyu Wang, Jingyu Mi, Hua Lu*, Shouhao Shi, et al. “Guided wave resonance-based digital holographic microscopy for high-sensitivity monitoring of refractive index,” Optics Letters 2024 (已录用)49. 苏盈文，陆华*等，“金属光栅表面等离激元与二硫化钨激子的强耦合特性,”光学学报 2024（已录用）。48. Dikun Li, Hua Lu*, Shouhao Shi, jianlin Zhao, Highly sensitive plasmonic sensing based on topological insulator nanoparticle, Nanoscale  15(45), 18300 (2023). (IF=6.7)47. Hua Lu*, Shouhao Shi, Dikun Li, Liping Hou, Shuwen Bo, Jianxu Zhao, Fajun Xiao, Dong Mao, Jianlin Zhao*, Strong Self‐Enhancement of Optical Nonlinearity in a Topological Insulator with Generation of Tamm State, Laser & Photonics Reviews 17, 2300269 (2023). (IF=11)46. Hua Lu*, Dikun Li, Shouhao Shi, Yangwu Li, Jianlin Zhao, Exciton-induced Fano resonance in metallic nanocavity with tungsten disulfide atomic layer, Optics Express 31,20761 (2023). （Editor suggestion）45. Dikun Li, Hua Lu*, and Jianlin Zhao, Topological insulator-based nonlinear optical effects and functional devices , J. Nonlinear Opt. Phys. Mater. 32(04), 2330002 (2023).44. S. Shi, H. Lu*, et al., "Asymmetric nanocavities with wide reflection color gamut for color printing," Nanotechnology 34  025201 (2023). 43. J. Zheng, H. Lu*, et al., "Plasmonic Fano-like resonance in double-stacked graphene nanostrip arrays," J. Opt. Soc. Am. B 39, 843 (2022). 42. Hua Lu*, et al., "Topological Insulator Plasmonics and Enhanced Light-Matter Interactions," Chapter 4 for Springer book: Plasmon-enhanced light-matter interactions, Springer International Publishing (2022)41. Dikun Li, Hua Lu*, et al., "Plasmon-enhanced photoluminescence from MoS2 monolayer with topological insulator nanoparticle," Nanophotonics 11, 995 (2022).40. Yangwu Li, Hua Lu*, et al., "Perfect light absorption in monolayer MoS2 empowered by optical Tamm states,"Chinese Optics Letters 19(10), 103801 (2021).39. H. Lu,et al., "Integration of topological insulator nanogap with atomic single layer for boosting photoluminescence," Optical Materials 122, 111786 (2021).38.H. Lu*, Z. Yue, Y. Li, Y. Zhang*, M. Zhang, W. Zeng, X. Gan, D. Mao, F. Xiao, T. Mei, W. Zhao, X. Wang, M. Gu, and J. Zhao*, “Magnetic plasmon resonances in nanostructured topological insulators for strongly enhanced light–MoS2 interactions,” Light: Science & Applications 9, 191 (2020). (Nature 子刊)37.H. Lu*？, Y. Li, Z. Yue, D. Mao, and J. Zhao*, “Graphene-tuned EIT-like effect in photonic multilayers for actively controlled light absorption of topological insulators,” Optics Express 28, 31893 (2020).36.B. Du, Y. Li, D. Yang*, H. Lu*？, “ High-performance optical sensing based on electromagnetically induced transparency-like effect in Tamm plasmon multilayer structures," Applied Optics 58(17), 4569 (2019). (Highlighted as an Editors' Pick)35.H. Lu？, et al., “Topological insulator based Tamm plasmon polaritons,” APL Photonics 4(4), 040801 (2019). (Invited article)34. H. Lu？, et al., “Induced reflection in Tamm plasmon systems,” Optics Express 27(4), 5383-5392 (2019).33. H. Lu, et al., “Sb2Te3 topological insulator: surface plasmon resonance and application in refractive index monitoring,” Nanoscale 11, 4759-4766 (2019). (Inside Front Cover，ESI 1% highly cited paper)32. 黎志文，陆华* 等，“光学薄膜塔姆态诱导石墨烯近红外光吸收增强,” 光学学报 39(1), 131001 (2019)。31. C. Tan, Z. Yue, Z. Dai, Q. Bao, X. Wang, H. Lu*, L. Wang*, “Nanograting-assisted generation of surface plasmon polaritons in Weyl semimetal WTe2,” Optical Materials 86, 421-423 (2018).30. H. Lu, et al., “Coupling-induced spectral splitting for plasmonic sensing with ultra-high figure of merit,” Chinese Physics B 27(11), 117302 (2018).29. H. Lu, et al.,“Plasmonic Fano spectral response from graphene metasurfaces in the MIR region,” Optical Materials Express 8(4),1058-1068 (2018).28. H. Lu, et al.,“Flexibly tunable high-quality-factor induced transparency in plasmonic systems,” Scientific Reports 8, 1558 (2018). (ESI 1% highly cited paper)27. H. Lu, et al., “Multiple plasmonically induced transparency for chip-scale bandpass filters in metallic nanowaveguides,” Optics Communications 414, 16 (2018).26. H. Lu, et al.,“Nearly perfect absorption of light in monolayer molybdenum disulfide supported by multilayer structures,” Optics Express 25, 21630 (2017). 25. H. Lu, et al., “Graphene-supported manipulation of surface plasmon polaritons in metallic nanowaveguides,” Photonics Research 5, 162 (2017). (ESI 1% highly cited paper)24. H. Lu, et al., “Strong plasmonic confinement and optical force in phosphorene pairs,” Optics Express 25, 5255 (2017).23. H. Lu, et al., “Chip-integrated plasmonic Schottky photodetection based on hybrid silicon waveguides,” Applied Physics B 123, 71 (2017).22. H. Lu, et al., “Tunable high-efficiency light absorption of monolayer graphene via Tamm plasmon polaritons,” Optics Letters 41, 4743 (2016).21. H. Lu, et al., “Nanowires-assisted excitation and propagation of mid-infrared surface plasmon polaritons in graphene,” Journal of Applied Physics 120, 163106 (2016).20. H. Lu, et al., “Graphene-based active slow surface plasmon polaritons,” Scientific Reports 5, 8443 (2015). (ESI 1% highly cited paper)19. H. Lu, et al., “Highly efficient plasmonic enhancement of graphene absorption at telecommunication wavelengths,” Optics Letters 40, 3647 (2015).18. H. Lu, “Plasmonic characteristics in nanoscale graphene resonator-coupled waveguides,” Applied Physics B 118, 61 (2015).  Before 201417. H. Lu, et al., “Optical bistability in subwavelength compound metallic grating,” Optics Express 21, 13794 (2013).16. H. Lu, et al., “Tunable high-channel-count bandpass plasmonic filters based on an analogue of electromagnetically induced transparency,” Nanotechnology 23, 444003 (2012). (Cover image)15. H. Lu, et al., “Plasmonic analogue of electromagnetically induced transparency in multi-nanoresonator-coupled waveguide systems,” Physical Review A 85, 053803 (2012). (ESI 1% highly cited paper)14. H. Lu, et al., “Plasmonic nanosensor based on Fano resonance in waveguide-coupled resonators,” Optics Letters 37, 3780 (2012). (ESI 1% highly cited paper)13. H. Lu, et al., “Enhancement of transmission efficiency of nanoplasmonic wavelength demultiplexer based on channel drop filters and reflection nanocavities,” Optics Express 19, 12885 (2011).12. H. Lu, et al., “Induced transparency in nanoscale plasmonic resonator systems,” Optics Letters 36, 3233 (2011).11. H. Lu, et al., “Ultrafast all-optical switching in nanoplasmonic waveguide with Kerr nonlinear resonator,” Optics Express 19, 2910 (2011). (ESI 1% highly cited paper)10. H. Lu, et al., “Tunable band-pass plasmonic waveguide filters with nanodisk resonators,” Optics Express 18, 17922 (2010). (ESI 1% highly cited paper)9. H. Lu, et al., “Manipulation of light in MIM plasmonic waveguide systems,” Chinese Science Bulletin 58, 3607 (2013) (Invited review).8. H. Lu, et al., “Tunable and robust reflection-free waveguides based on a gyromagnetic photonic crystal,” Journal of Electromagnetic Waves and Applications 25, 1752 (2011).7. H. Lu, et al., “Optimization of supercontinuum generation in air-silica nanowires,” Journal of the Optical Society of America B 27, 904 (2010).6. H. Lu, et al., “Analysis of nanoplasmonic wavelength demultiplexing based on MIM waveguides,” Journal of the Optical Society of America B 28, 1616 (2011).5. H. Lu, et al., “Nanoplasmonic triple-wavelength demultiplexers in two-dimensional metallic waveguides,” Applied Physics B 103, 877 (2011).4. H. Lu, et al., “Optical bistability in MIM plasmonic Bragg waveguides with Kerr nonlinear defects,” Applied optics 50, 1307 (2011).3. G. Wang*, H. Lu*, “Unidirectional excitation of surface plasmon polaritons in T-shaped waveguide with nanodisk resonator,” Optics Communications 285, 4190 (2012).2. H. Lu, et al., “Multi-channel plasmonic waveguide filters with disk-shaped nanocavities,” Optics Communications 284, 2613 (2011). 1. H. Lu, et al., “Second-harmonic generation from metal-film nanohole arrays,” Applied optics 49, 2347 (2010).

综合介绍

学术文献 Academic Literature