Name：Xiaofeng LI

Professor Xiaofeng LI received B.Eng. and Ph.D. (hons.) degrees in Communication Engineering from Southwest Jiaotong University, China, in 2002 and 2007, respectively. From 2007 to 2010, he was working as a research fellow in School of Electrical and Electronic Engineering, Nanyang Technological University, Singapore. From 2010 to 2011, he was employed in Imperial College London as a research associate. He began to work in Soochow University as a full professor since January 2012. He is now the dean of School of Optoelectronic Science and Engineering as well as the vice president of Soochow University. His interests include nanophotovoltaics, surface-plasmon physics and devices, hot-electron photodetection, optical sensing, etc. He has already authored over 200 journal papers and is an active referee for ~ 50 journals, e.g., Science, Nature Series journals, Science Advances, Advanced Materials, etc. Prof. Li is a senior member of IEEE and Chines Optical Society. He has been serving as an associate editor for OSA Applied Optics and IEEE Photonics journal for two terms (2016-2021), and is now the Editorial member of PhotoniX and several other journals.

09/2002 – 03/2007, PhD,Southwest Jiaotong University, China

09/1998 – 07/2002, BEng,Southwest Jiaotong University, China

05/2022 –,Vice President, Soochow University, China

06/2018 –,Distinguished Professor/Dean, School of Optoelectronic Science and Engineering, Soochow University;Vice Director, Key Lab of Modern Optical Technologies of Education Ministry of China;Director, Key Lab of Optical Engineering Centre of Education Ministry of China, Soochow University, China

01/2014 – 06/2018,Distinguished Professor/Deputy Dean, School of Optoelectronic Information Science and Engineering, Soochow University;Vice Director, Key Lab of Modern Optical Technologies of Education Ministry of China &Key Lab of Advanced Optical Manufacturing Technologies of Jiangsu Province, Soochow University, China

01/2012 –,Distinguished Professor, Institute of Modern Optical Technologies, Soochow University, China

Interests:Nanophotonics; photovoltaics; plasmonics; photoconversion technologies

07/2010 – 12/2011,Research Associate, Imperial College London, United Kingdom

Supervisor: Prof.Stefan A. Maier

Interests:Plasmonics; photovoltaics

08/2007 – 07/2010,Research Fellow, Nanyang Technological University, Singapore

05/2007 – 07/2007,Project Officer, Nanyang Technological University, Singapore

Supervisor:Prof.Siu Fung Yu

Interests:Semiconductor lasers (DFB, surface-emitting, and micro-cavity lasers, etc); plasmonic waveguide and lasers; periodic structures; electromagnetic computation; nanotechnology

09/2002 – 01/2007,PhD, Southwest Jiaotong University (SWJTU), China

Supervisor:Prof.Wei Pan

Thesis title:Nonlinear dynamics of vertical-cavity surface-emitting lasers subject to external optical feedback

Interests:Semiconductor lasers; laser nonlinear dynamics; chaos synchronization and communication

9/1998 – 07/2002,BEng, Southwest Jiaotong University, China

Associate Editorof Applied Optics (OSA), 2016/01-2022/01/31.

Associate Editorof IEEE Photonics Journal, 2016/09-2021/12/31.

Editorial Boardof Laser & Optoelectronics Progress

Senior Editorof PhotoniX

Travelling Lecturerof Optical Society of America (OSA)

Senior Memberof IEEE; Senior Memberof Chinese Optical Society (COS)

OSA Member; SPIE Member

Reviewer of over 40 journalsfrom NGP,ACS,AIP, Elsevier, IEEE, IET, IOP, OSA, Springer, Wiley, etc

1、Design and fabrication of 3rd-generation high-performance solar cells

2、Advanced photodetection technologies and applications

3、Micro/nano fabrication and energy devices

Associate Editorof Applied Optics (OSA), 2016/01-2022/01/31.

Associate Editorof IEEE Photonics Journal, 2016/09-2021/12/31.

Editorial Boardof Laser & Optoelectronics Progress

Senior Editorof PhotoniX

Travelling Lecturerof Optical Society of America (OSA)

Senior Memberof IEEE; Senior Memberof Chinese Optical Society (COS)

OSA Member; SPIE Member

Reviewer of over 40 journalsfrom NGP,ACS,AIP, Elsevier, IEEE, IET, IOP, OSA, Springer, Wiley, etc

1) Fundamentals of Photonics (Graduated students)

2) Your Design on Solar Cells (Undergraduates)

3) Optics Advances (Graduated students)

4) Advances in Optoelectronics (Undergraduates)

l 2022 the National Key Research and Development Program of China (PI)

l 2021 Key International Collaboration Project from National Natural Science Foundation of China (PI)

l 2018 National Natural Science Foundation of China (PI)

l 2017 Major Projects of Natural Science Research in Colleges and Universities of Jiangsu (PI)

l 2016 National Natural Science Foundation of China (PI)

l 2012 Fostering major project by National Natural Science Foundation of China (PI)

l 2012 Young-Researcher Project from National Science Foundation of China (PI)

l Natural Science Foundation of the Jiangsu Higher Education Institutions of China (PI)

l Ph.D. Programs Foundation of Ministry of Education of China (PI)

l National Program on Key Basic Research Project (youth 973 Program) (2^ndinvestigator)

Year 2024

[1] Luolei Shi, Zhenhai Yang^*, Yuqi Zhang, Zhenhai Ai, Yining Bao, Tianshu Ma, Linling Qin, Guoyang Cao^*, Changlei Wang, and Xiaofeng Li^*. Correlation carrier dynamics and performance for perovskite solar cells.Solar RRL2023. (accepted)

[2] Huayang Wang^#, Tianshu Ma^#, Zhanghao Wu, Yue Zhao, Cong Chen, Xinxing Yin, Lin Hu, Fang Yao, Qianqian Lin, Shaojun Wang^*, Dewei Zhao^*, Xiaofeng Li^*, and Changlei Wang^*. Hole transport layer-free low-bandgap perovskite solar cells for efficient all-perovskite tandems.Advanced Materials2023. (accepted)

Year 2023

[3] Jingming Zheng^#, Zhiqin Ying^#, Zhenhai Yang^#,*, Zedong Lin, He Wei, Li Chen, Xi Yang^*, Yuheng Zeng, Xiaofeng Li^*, and Jichun Ye^*. Polycrystalline silicon tunneling-recombination layers for high-efficiency perovskite/TOPCon tandem solar cells.Nature Energy2023, 8:1250‒1261.

[4] Zhenghe Zhang^#, Chaojie Xu^#, Chen Liu, Man Lang, Minghao Li, Wanli Lu, Zefeng Chen, Chinhua Wang, Shaojun Wang^*, and Xiaofeng Li^*. Dual control of enhanced quasi-bound states in the continuum emission from resonant c-Si metasurfaces.Nano Letters2023, 23(16):7584-7592.

[5] Weijia Shao, Weihao Cui, Junhui Hu, Yongmei Wang, Jian Tang, and Xiaofeng Li^*. Planar hot-electron photodetection with polarity-switchable photocurrents controlled by working wavelength.Optics Express2023, 15(17):25220‒25229.

[6] Shengchen Ke, Linling Qin^*, Ruoxi Zhang, Weijian Zhu, Wenxiang Lu, Lu Ma, Shaolong Wu^*, and Xiaofeng Li^*. Towards self-driven and enzyme-free sweat glucose photoelectrochemical sensing via decorating CuO nanoparticles on TiO₂hierarchical nanotubes.Surface and Interfaces2023,40:103102.

[7] Yixuan Jin^#, Kai Wu^#, Bining Sheng, Wentao Ma, Zefeng Chen^*, and Xiaofeng Li^*. Plasmonic bound states in the continuum to tailor exciton emission of MoTe₂.Nanomaterials2023, 13:1987.

[8] Cheng Zhang^*, Binglin Huang, Haoyu Li, Hui Chen, Tong Yu, Bingchang Zhang^*, Shaojun Wang, Changxu Liu, Yu Luo, Stefan A. Maier, and Xiaofeng Li^*. Plasmonic nanoneedle arrays with enhanced hot electron photodetection for near-IR imaging.Advanced Functional Materials2023:2304368.

[9] Ruoxi Zhang, Shengchen Ke, Wenxiang Lu, Weijian Zhu, Lu Ma, Linling Qin^*, Shaolong Wu^*, and Xiaofeng Li^*. Constructing a Si-CuO core-shell nanowire heterojunction photoanode for enzyme-free and highly-sensitive glucose sensing.Applied Surface Science2023, 632:157593.

[10] Guoyang Cao, Changlei Wang, Yu Luo, and Xiaofeng Li^*. All-in-one photoelectric logic gates by Dember photodetectors.Photonics Research2023, 11(7):1148‒1153.

[11] Jining Wang, Yaohui Zhan^*, Wei Ma, Hongyu Zhu, Yao Li, and Xiaofeng Li^*. Machine learning enabled rational design for dynamic thermal emitters with phase-change materials.iScience2023, 26(6):106857.

[12] Yue Zhao^#, Changlei Wang^#,*, Tianshu Ma, Luwei Zhou, Zhanghao Wu, Huayang Wang, Cong Chen, Zhenhua Yu, Weiwei Sun, Aolin Wang, Hao Huang,Bingsuo Zou,Dewei Zhao^*, and Xiaofeng Li^*.Reduced 0.418 VV_OC-deficit of 1.73 eV wide-bandgap perovskite solar cells assisted by dual chlorides for efficient all-perovskite tandems.Energy & Environmental Science2023,16(5):2080‒2089.

[13] Tianshu Ma, Yidan An, Zhenhai Yang, Zhenhai Ai, Yuqi Zhang, Changlei Wang, and Xiaofeng Li^*. Thermodynamic processes of perovskite photovoltaic devices: mechanisms, simulations, and manipulation.Advanced Functional Materials2023:2212596.

[14] Yuqi Zhang, Zhenhai Yang^*, Tianshu Ma, Zhenhai Ai, Changlei Wang, and Xiaofeng Li^*. A theoretical investigation of transport layer-free homojunction perovskite solar cells via a detailed photoelectric simulation.Advanced Energy Materials2023:2203366.

[15] Zhenhe Zhang, Pengbo Liu, Zefeng Chen, Wanli Lu, Ping Bai, Jaime Gomez Rivas, Stefan A. Maier, Shaojun Wang^*, and Xiaofeng Li^*. High-Q collective Mie resonances in monocrystalline silicon nanoantenna arrays for the visible light.Fundamental Research2023, 3:822-830.

[16] Ihsan Ullah, Junjun Guo, Changlei Wang, Zeke Liu, Xiaofeng Li^*, Lin Jiang, Jianyu Yuan, and Wanli Ma^*. Design and analysis of high-efficiency perovskite solar cell using the controllable photonic structure and plasmonic nanoparticles.Journal of Alloys and Compounds2023, 960:170994.

[17] Zhenhai Ai, Tianshu Ma, Yidan An, Changlei Wang, Guoyang Cao^*, Dong Ma^*, and Xiaofeng Li^*. Transient response mismatch: a limiting factor of perovskite photodetectors.Advanced Optical Materials2023, 11:2202381.

[18] Yuehao Zhang, Zhenghe Zhang, Chaojie Xu, Wanli Lu, Zefeng Chen, Changlei Wand, Fajun Xiao, Shaojun Wang^*, and Xiaofeng Li. Precisely constructing hybrid nanogap arrays via wet-transfer of dielectric metasurfaces onto a plasmonic mirror.Optics Express2023, 31(21): 34280‒34291.

[19] Yang Liu, Hao Wu, Guozheng Shi, Yusheng Li, Yiyuan Gao, Shiwen Fang, Haodong Tang, Wei Chen, Tianshu Ma, Irfan Khan, Kai Wang, Changlei Wang, Xiaofeng Li, Qing Shen, Zeke Liu^*, and Wanli Ma^*. Merging passivation in synthesis enabling the lowest poen-circuit voltage loss for PbS quantum dot solar cells.Advanced Materials2023, 35:2207293.

[20] Qianru Yang, Hao Hu, Xiaofeng Li, and Yu Luo^*. Cascaded parametric amplification based on spatiotemporal modulations.Photonics Research2023, 11(5): B125‒B135.

Year 2022

[21] Zhenhai Ai, Donghui Wu, Tianshu Ma, Yue Zhao, Yidan An, Changlei Wang, and Xiaofeng Li^*. Physics, simulation, and experiment of perovskite solar cells with addressing hysteresis effect.Solar RRL2022:2200606.

[22] Tingting Liu, Cheng Zhang^*, and Xiaofeng Li^*.Strain engineering for high-performance hot-carrier photodetection.Journal of Applied Physics2022, 132(6):064901.

[23] Tingting Liu, Jun Hu^*, Yu Luo, and Xiaofeng Li^*. Hot-carrier physics and materials: an insight from electronic structure.Physical Review Applied2022, 18:014058.

[24] Tingting Liu, Cheng Zhang^*, and Xiaofeng Li^*.2D MXenes for hot-carrier photodetection.Advanced Optical Materials2022:2201153.

[25] Tianshu Ma, Yidan An, Sheng Li, Yue Zhao, Huayang Wang, Changlei Wang^*, Stefan A. Maier, and Xiaofeng Li^*.Low-bandgap perovskite concentrator solar cells: device physics, optoelectronic simulation, and experiment.ACS Applied Materials and Interfaces2022, 14:29856‒29866.

[26] Changlei Wang, Yue Zhao, Tianshu Ma, Yidan An, Rui He, Jingwei Zhu, Cong Chen, Shengqiang Ren, Fan Fu^*, Dewei Zhao^*and Xiaofeng Li^*. A universal close-space annealing strategy toward high-quality perovskite absorbers enabling efficient all-perovskite tandem solar cells.Nature Energy2022, 7:744‒753.

[27] Junjun Chen, Sheng Li, Tianshu Ma, Donghui Wu, Changlei Wang^*, Dewei Zhao^*, and Xiaofeng Li^*. Managing lead leakage in efficient perovskite solar cells with phosphate interlayers.Advanced Materials Interfaces2022:2200570.

[28] Tingting Liu, Qianjun Wang, Cheng Zhang^*, Xiaofeng Li^*, and Jun Hu^*. High performance of hot-carrier generation, transport and injection in TiN/TiO₂junction.Frontiers of Physics2022, 17(5):53509.

[29] Donghui Wu, Zhenhai Ai, Sheng Li, Junjun Chen, Yue Zhao, Tianshu Ma, Huayang Wang, Changlei Wang^*, and Xiaofeng Li^*. Efficient flexible perovskite solar cells with reduced hysteresis employing cobalt nitrate treated SnO₂.Solar RRL2022: 2200210.

[30] Liujing Li, Zhongyuan Zhou, Peiji Guo, Xiaofeng Li^*, and Shaolong Wu^*. Photo-assisted decoration of Ag-Pt nanoparticles on Si photocathodes for reducing overpotential toward enhanced photoelectrochemical water splitting.Science China Materials2022, 65:3033‒3042.

[31] Xiudong Xu^#, Jinxin Gu^#, Haipeng Zhao, Xinyuan Zhang, Shuliang Dou, Yao Li, Jiupeng Zhao, Yaohui Zhan^*, and Xiaofeng Li^*. Passive and dynamic phase-change-based radiative cooling in outdoor weather.ACS Applied Materials & Interfaces2022, 14(12):14313‒14320.

[32] Cheng Zhang, Yu Luo, Stefan A. Maier, Xiaofeng Li^*. Recent progress and future opportunities for hot carrier photodetectors: from ultraviolet to infrared bands.Laser & Photonics Reviews2022, 16:2100714.

[33] Guoyang Cao, Haoyu Zhang, Changlei Wang, and Xiaofeng Li^*. Self-driving perovskite Dember photodetectors.Advanced Optical Materials2022, 10:2101821.

[34] Cheng Zhang, Tingting Liu, Liang Li, Ti Sun, Shaolong Wu, Chinhua Wang, and Xiaofeng Li^*.Planar dual-layer system for ultra-broadband absorption and hot-carrier photodetection in longwave near-infrared band.IEEE J. Selected Topics in Quantum Electronics2022, 28(2):3800109.

[35] Qinyu Qian^#,*, Peiqing Sun^#, Cheng Zhang^*, Tingting Liu, Haitao Chen, Li Fan, Liwen Cheng, Liang Zhao, Xiaofeng Li, and Chinhua Wang. A broadband and polarization-independent metasurface perfect absorber for hot-electron photoconversion.Nanoscale2022, 14:14801‒14806.

[36] Jiayu Lu, Huayang Wang, Tingbing Fan, Dong Ma^*, Changlei Wang^*, Shaolong Wu^*, and Xiaofeng Li. Back interface passivation for efficient low-bandgap perovskite solar cells and photodetectors.Nanomaterials2022, 12:2065.

[37] Jin Chuan Zhang, Hong Yang Zhu^#, Xiao Mei Zhu, Shan Shan Wang, Fei Liang Chen, Ke Li, Xiaofeng Li, and Wei Li Zhang^*. Scattering-assisted logical WGM laser in liquid crystal micropillar.Journal of Lightwave Technology2022, 40(15):5216‒5223.

[38] Xiao Dai^#, Yining Jiang^#, Xiaohan Wang, Fengnan Chen, Liang Gao, Xiaofeng Li, and Guifu Zou^*. Mailllard reaction-derived laser lithography for printing functional inorganics.Science China Chemistry2022, 65(7):1306‒1314.

[39] Yifan Yu, Lu Ma, Linling Qin^*, Wenxiang Lu, Cheng Zhang, and Shaolong Wu^*, Xiaofeng Li. Unbiased glucose biosensing based on a Schottky junction comprised of Au nanoparticle-decorated TiO2‑coated Al films.ACS Applied Nano Materials2022, 5:11776‒11786.

[40] Wenyan Wang, Cheng Zhang, Kaifang Qiu, Guohui Li, Aiping Zhai^*, Yuying Hao, Xiaofeng Li, and Yanxia Cui^*. Enhancing hot-electron photodetection of a TiO₂/Au Schottky junction by employing a hybrid plasmonic nanostructure.Materials2022, 15:2737.

[41] Pengbo Liu^#, Zhenghe Zhang^#, Man Lang, Wanli Lu, Ping Bai, Zefeng Chen^*, Shaojun Wang^*, and Xiaofeng Li. Manipulating the directional emission of monolayer semiconductors by dielectric nanoantenna arrays.Journal of Optics2022, 24:024005.

Year 2021

[42] Guoyang Cao, Haoyu Zhang, Guoqing Chen^*, and Xiaofeng Li^*. Ambipolar self-driving polarized photodetection.ACS Photonics2021, 8(8):2459−2465.

[43] Pei Jiang^#, Pei Zhou^#,Nianqiang Li^*, Penghua Mu, and Xiaofeng Li^*. Characterizing the chaotic dynamics of a semiconductor nanolaser subjected to FBG feedback.Optics Express202129(12):17815−17830.

[44] Luwei Zhou^#, Cheng Zhang^#,*, Liujing Li, Tingting Liu, Ke Li, Shaolong Wang^*, and Xiaofeng Li^*. Nanobowls-assisted broadband absorber for unbiased Si-based infrared photodetection.Optics Express2021, 29(10):15505−15516.

[45] Haipeng Zhao, Yaohui Zhan^*, Shuliang Dou, Liang Wang, Yao Li, and Xiaofeng Li^*. Passive radiative temperature regulator: principles and absorption-emission manipulation.Solar Energy Materials & Solar Cells2021, 229:111143.

[46] Yidan An, Tianshu Ma, and Xiaofeng Li^*. Energy tracing of photovoltaic cells.Solar RRL2021, 5:2100199. (inside front cover)

[47] Yuxiang Guan^#, Guoyang Cao^#, and Xiaofeng Li^*. Single-nanowire photodetectors with core-shell radial Schottky junction for self-powering application.Applied Physics Letters2021, 118:153904.

[48] Yibo Zou, Markus Kaestner, Eduard Reithmeier, Tuo Shi, and Xiaofeng Li^*. Development and multiscale evaluation of microscopic stitching with tilt compensation.Measurement2021, 176:109783.

[49] Guoyang Cao, Guoqing Chen^*, and Xiaofeng Li^*. Core-shell single-nanowire photodetector with radial carrier transport: an opportunity to break the responsivity-speed trade-off.Advanced Electronic Materials2021, 7(7):2000920. (back cover)

[50] Chenhong Xiao^#, Zhongyuan Zhou^#, Liujing Li, Zhenhai Yang, Shaolong Wu^*, and Xiaofeng Li^*. Direct growth of hematite film on p⁺n-silicon micro-pyramid arrays for low-bias water splitting.Solar Energy Materials & Solar Cells2021, 224:110987.

[51] Yaohui Zhan^#, Lei Zhang^#, Mohsen Rahmani^#, Vincenzo Giannini, Andrey E., Miroshnichenko, Minghui Hong, Xiaofeng Li, Stefan A. Maier, and Dangyuan Lei^*. Synthetic plasmonic nanocircuits and the evolution of their correlated spatial arrangement and resonance spectrum.ACS Photonics2021, 8:166-174.

[52] Hongyang Zhu, Weili Zhang^*, Jinchuan Zhang, Rui Ma^*, Zhao Wang, Yunjiang, Rao, and Xiaofeng Li. Single-shot interaction and synchronization of random microcavity lasers.Advanced Materials Technologies2021, 6(9):2100562

Year 2020

[53] Sheng Li^#, Changlei Wang^#,*, Dewei Zhao^*, Yidan An, Yue Zhao, Xingzhong Zhao^*, and Xiaofeng Li^*.Flexible semitransparent perovskite solar cells with gradient energy levels enable efficient tandems with Cu(In,Ga)Se₂.Nano Energy2020, 78:105478.

[54] Hao Mei^#, Yuliang Wu^#,Changlei Wang^*, Shengqiang Ren, Mingdi Zhang, Sheng Li, Haitao Dai, Dewei Zhao, Qingguo Du^*and Xiaofeng Li^*. Synergistic engineering of bromine and ctyltrimethylammonium chloride molecule enabling efficient and stable flexible perovskite solar cells.Journal of Materials Chemistry A2020, 8:19425-19433.

[55] Pei Jiang^#, Pei Zhou^#, Nianqiang Li^*, Penghua Mu, and Xiaofeng Li^*. Optically injected nanolasers for time-delay signature suppression and communications.Optics Express2020, 28(18):26421-26435.

[56] Liujing Li, Shaolong Wu^*, Zhongyuan Zhou, Peiji Guo, and Xiaofeng Li^*.Size-dependent performances in homogeneous, controllable, and large-area silicon wire array photocathode.Journal of Power Sources2020, 473:228580.

[57] Yidan An^#, Changlei Wang^#, Guoyang Cao, and Xiaofeng Li^*.Heterojunction perovskite solar cells: opto-electro-thermal physics, modeling, and experiment.ACS Nano2020, 14(4):5017-5026.(IF 15.881)

[58] Zhongyuan Zhou, Shaolong Wu^*, Chenhong Xiao, Liujing Li, and Xiaofeng Li^*. Underlayer engineering into the Sn-doped hematite photoanode for facilitating carrier extraction.Physical Chemistry Chemical Physics2020, 22:7306-7313.

[59] Chenhong Xiao, Zhongyuan Zhou, Liujing Li, Shaolong Wu^*, and Xiaofeng Li^*. Tin and oxygen-vacancy Co-doping into hematite photoanode for improved photoelectrochemical performances.Nanoscale Research Letters2020, 15:54.

[60] Hao Ding, Shaolong Wu^*, Cheng Zhang, Liujing Li, Qingxin Sun, Luwei Zhou, and Xiaofeng Li^*. Tunable infrared hot-electron photodetection by exciting gap-mode plasmons with wafer scale gold nanohole arrays.Optics Express2020, 28(5):6511-6520.

[61] Pei Liu^#, Yue Sun^#, Shaofu Wang, Huijie Zhang, Youning Gong, Fangjie Li, Yunfan Shi, Yunxiao Dua, Xiaofeng Li^*, Shi-shang Guo^*,Qidong Tai^*, Changlei Wang^*, Xing-Zhong Zhao^*. Two dimensional graphitic carbon nitride quantum dots modified perovskite solar cells and photodetectors with high performances.Journal of Power Sources2020, 451:227825.

[62] Jun Du, Yidan An, Donghui Wu, Changlei Wang, Canyan Zhu, Xiaofeng Li, and Dong Ma^*. Easy-to-process and high-performance colorful perovskite solar cells using a multilayer planar filter.Optics Letters2020, 45(22):6326-6329.

Year 2019

[63] Chunxiang Sheng^#, Yidan An^#, Jun Du, and Xiaofeng Li^*. Colored radiative cooler under optical Tamm resonance.ACS Photonics2019, 6(10):2545-2552.

[64] Yidan An^#, Chunxiang Sheng^#, and Xiaofeng Li^*. Radiative cooling of solar cells: opto-electro-thermal physics and modeling.Nanoscale2019, 11, 17073-17083.

[65] Guoyang Cao, Yidan An, Qiaoliang Bao, and Xiaofeng Li^*. Physics and optoelectronic simulation of photodetectors based on 2D materials.Advanced Optical Materials2019, 7(15):1900410.

[66] Changlei Wang^*, Zhaoning Song, Dewei Zhao, Rasha A. Awni, Chongwen Li, Niraj Shrestha, Cong Chen, Xinxing Yin, Dengbing Li, Randy J. Ellingson, Xingzhong Zhao, Xiaofeng Li^*, and Yanfa Yan^*. Improving performance and stability of planar perovskite solar cells through grain boundary passivation with block copolymer.Solar RRL2019, 3(9):1900078.

[67] Qingxin Sun^#, Cheng Zhang^#, Weijia Shao, and Xiaofeng Li^*.Photodetection by hot electrons or hot holes: a comparable study on physics and performances.ACS Omega2019, 4(3):6020-6027.

[68] Liang Li, Shaolong Wu^*, Liujing Li Zhongyuan Zhou, Hao Ding, Chenhong Xiao, and Xiaofeng Li^*. Gap-mode excitation, manipulation, and refractive-index sensing application by gold nanocube arrays.Nanoscale2019, 11: 5467-5473.

[69] Linling Qin^#, Shaolong Wu^#, Cheng Zhang, and Xiaofeng Li^*.Narrowband and full-angle refractive index sensor based on a planar multilayer structure.IEEE Sensors Journal2019, 19(8):2924-2930.

[70] Zhongyuan Zhou, Shaolong Wu^*, Liujing Li, Liang Li, and Xiaofeng Li^*. Regulating the Si/α-Fe₂O₃microwire photoanode by conformal Al₂O₃intermediate layer for water splitting.ACS Applied Materials & Interfaces2019, 11(6):5978-5988.(Supplementary Cover)

[71] Weijia Shao, Qianru Yang, Cheng Zhang, Shaolong Wu, and Xiaofeng Li^*. Planar dual-cavity hot-electron photodetectors.Nanoscale2019, 11:1396-1402.

[72] Cheng Zhang, Guoyang Cao, Shaolong Wu, and Weijia Shao, Vincenzo Giannini, Stefan A. Maier, andXiaofeng Li^*.Thermodynamic loss mechanisms and strategies for efficient hot-electron photoconversion.Nano Energy2019, 55, 164-172.

[73] Jun Du^#, Yiand An^#, Cheng Zhang, Canyan Zhu, Xiaofeng Li, and Dong Ma^*.Photonic design and electrical evaluation of dual-functional solar cells for energy conversion and display applications.Nanoscale Research Letters2019, 14:70.

[74] Bowen Sui, Yuting Xu, Ziwei Wang, Cheng Zhang, Linling Qin, Xiaofeng Li, and Shaolong Wu^*. Simultaneously performing optical and electrical responses from a plasmonic sensor based on gold/silicon Schottky junction.Optics Express2019, 27(26):38382-38390.

[75] Tong Yu, Cheng Zhang^*, Huimin Liu, Jianhui Liu, Ke Li, Linling Qin, Shaolong Wu^*, Xiaofeng Li. Planar, narrowband, and tunable photodetection in the nearinfrared with Au/TiO2 nanodiodes based on Tamm plasmons.Nanoscale2019, 11: 23182-23187.

[76] Zhongyuan Zhou, Shaolong Wu^*, Chenhong Xiao, Liujing Li, Weijia Shao, Hao Ding, Long Wen, and Xiaofeng Li. Self-improvement of solar water oxidation for the continuously-irradiated hematite photoanode.Dalton Transactions2019, 48:15151-15159.

[77] Fengnan Chen, Chen Yang, Wenjing Mao, Heng Lu, Kevin G. Schädler, Antoine Reserbat-Plantey, Johann Osmond, Guoyang Cao1, Xiaofeng Li, Chinhua Wang, Ying Yan^*, and Joel Moser^*. Vibration detection schemes based on absorbance tuning in monolayer molybedenum disulfide mechanical resonators.2D Materials2019, 6(1):011003.

[78] Wei Li Zhang^*, Xin Jie Li, Shan Shan Wang, Chu Yuan Zheng, Xiao Feng Li, and Yun Jiang Rao. Polaritonic manipulation based on spin-selective optical Stark effect in WS₂and Tamm plasmons hybrid structure.Nanoscale2019, 11, 4571-4577.

Year 2018

[79] Cheng Zhang, Qinyu Qian, Linling Qin, Xin Zhu, Chinhua Wang^*, and Xiaofeng Li^*. Broadband light harvesting for highly efficient hot-electron application based on conformal metallic nanorod arrays.ACS Photonics2018, 5:5079-5085.

[80] Yidan An, Aixue Shang, Guoyang Cao, Shaolong Wu, Dong Ma^*, and Xiaofeng Li^*. Perovskite solar cells: optoelectronic simulation and optimization.Solar RRL2018, 2(11): 1800126.(Frontispiece Cover)

[81] Zhongyuan Zhou, Shaolong Wu^*, Linling Qin, Liang Li, Liujing Li, and Xiaofeng Li^*. Modulating oxygen vacancy in Sn-doped hematite film grown on silicon microwires for efficient photoelectrochemical water oxidation.Journal of Materials Chemistry A2018, 6, 15593.(Back Cover)

[82] Qiaoping Zhang^#, Cheng Zhang^#, Linling Qin, and Xiaofeng Li^*. Polarization-insensitive hot-electron infrared photodetection by double Schottky junction and multilayer grating.Optics Letters2018, 43(14), 3325-3328.

[83] Qianru Yang, Cheng Zhang, Shaolong Wu,Shaojuan Li, Qiaoliang Bao, Vincenzo Giannini,Stefan A. Maier,andXiaofeng Li^*.Photonic surface waves enabled perfect infrared absorption by monolayer graphene.Nano Energy2018, 48:161-169.

[84] Linling Qin, Shaolong Wu^*, Jian-hua Deng, Liujing Li, and Xiaofeng Li^*.Tunable light absorbance by exciting the plasmonic gap mode for refractive index sensing.Optics Letters2018, 43(7):1427-1430.

[85] Qianru Yang, Linling Qin, Guoyang Cao, Cheng Zhang, and Xiaofeng Li^*.Refractive index sensor based on graphene-coated photonic surface wave resonance.Optics Letters2018, 43(4):639-642.

[86] Ibrahim M. Nassar, Shaolong Wu^*, Liang Li, and Xiaofeng Li^*.Facile preparation ofn-type LaFeO₃perovskite film for efficient photoelectrochemical water splitting.ChemistrySelect2018, 3:968-972.

[87] Li Chen, Shaolong Wu^*, Dong Ma, Aixue Shang, and Xiaofeng Li^*. Optoelectronic modeling of the Si/α-Fe2O3 heterojunction photoanode.Nano Energy2018, 43:177-183.

[88] Xiaofeng Xiao^*, Xiaofeng Li, Joshua D. Caldwell, Stefan A. Maier, and Vincenzo Giannini. Theoretical analysis of graphene plasmon cavities.Applied Materials Today2018, 12:283−293.

Year 2017

[89] Aixue Shang, Yidan An, Dong Ma^*, and Xiaofeng Li^*. Optoelectronic insights into the photovoltaic losses from photocurrent, voltage, and energy perspectives.AIP Advances2017, 7:085019.

[90] Ke Li^#, Jamie M. Fitzgerald^#, Xiaofei Xiao^#,*, Joshua D. Caldwell, Cheng Zhang, Stefan A. Maier, Xiaofeng Li^*, and Vincenzo Giannini.Graphene plasmon cavities made with silicon carbide.ACS Omega2017, 2:3640-3646.

[91] Yaohui Zhan and Xiaofeng Li^*. Plasmonics and antenna effect mediated super absorption in ultrathin film via metallic-core/ semiconductor-shell nanowire design.IEEE Photonics Technology Letters2017, 29(11): 893-896.

[92] Linling Qin, Cheng Zhang, Runfeng Li, and Xiaofeng Li^*.Silicon-gold core-shell nanowire array for optically and electrically characterized refractive index sensor based on plasmonic resonance and Schottky junction.Optics Letters2017, 42(7):1225-1228.

[93] Cheng Zhang, Kai Wu, Vincenzo Giannini, Xiaofeng Li^*. Planar hot-electron photodetection with Tamm plasmon.ACS Nano2017, 11:1919−1727.

[94] Aixue Shang and Xiaofeng Li^*.Photovoltaic devices: opto-electro-thermalphysics and modeling.Advanced Materials2017, 29:1603492.

[95] Runfeng Li^#, Cheng Zhang^#, and Xiaofeng Li^*.Schottky hot-electron photodetector by cavity-enhanced optical Tamm resonance.Applied Physics Letters2017, 110:013902.

[96] Jimu Yan^#, Shaolong Wu^#, Xiongfei Zhai, Xiang Gao, and Xiaofeng Li^*.Si microwire array photoelectrochemical cells: stabilized and improved performances with surface modification of Pt nanoparticles and TiO₂thin film.Journal of Power Sources2017, 342:460−466.

[97] Jian Yuan^#, Weiliang Ma^#, Lei Zhang^#, Yao Lu, Meng Zhao, Hongli Guo, Jin Zhao, Wenzhi Yu, Yupeng Zhang, Kai Zhang, Hui Ying Hoh, Xiaofeng Li, Kian Ping Loh, Shaojuan Li^*, Cheng-Wei Qiu^*and Qiaoliang Bao^*.Infrared nanoimaging reveals the surface metallic plasmons in topological insulator.ACS Photonics2017, 4:3055-3062.

[98] Zhao Ji Yang, Wei Li Zhang^*, Rui Ma, Xiang Dong, Sofie Lindskov Hansen, Xiaofeng Li, and Yunjiang Rao.Nanoparticle mediated microcavity random laser.Photonics Research2017, 5(6):557-560.

[99] Liyue Zhang, Wei Pan, Penghua Mu, Xiaofeng Li, Shuiying Xiang, Weiling Zhang, Ning Jiang, and Nianqiang Li. The role of master laser with feedback in time-delay signature suppression of semiconductor laser subject to chaotic optical injection.International Journal of Bifurcation and Chaos2017, 27(11):1750196.

Year 2016

[100]Xiang Gao^#, Shaolong Wu^#,*, Jimu Yan, Xiongfei Zhai, and Xiaofeng Li^*. Stabilized and improved photoelectrochemical responses of silicon nanowires modified with Ag@SiO₂nanoparticles and crystallized TiO₂film.ACS Applied Materials & Interfaces2016, 8:30072−30078.

[101]Gai Feng, Cheng Zhang, Yaohui Zhan, and Xiaofeng Li^*. Enhanced light-harvesting capability for silicon single-nanowire solar cells coupled with metallic cavity.Optics Express2016, 24(26):A1505−A1513.

[102]Guoyang Cao, Aixue Shang, Cheng Zhang, Youpin Gong, Shaojuan Li, Qiaoliang Bao, and Xiaofeng Li^*.Optoelectronic investigation of monolayer MoS₂/WSe₂verticalheterojunction photoconversion devices.Nano Energy2016, 30:260−266.

[103] Cheng Zhang, Zhenhai Yang, Kai, Wu, and Xiaofeng Li^*.Design of asymmetric nanovoid resonator for silicon-based single-nanowire solar absorbers.Nano Energy2016, 27:611−618.

[104] Cheng Zhang, Kai Wu, Yaohui Zhan, Vincenzo Giannini, and Xiaofeng Li^*.Planar microcavity-integrated hot-electron photodetector.Nanoscale2016, 8:10323−10329.

[105] Zhenhai Yang^#, Guoyang Cao^#, Aixue Shang, Dang Yuan Lei, Cheng Zhang, Pingqi Gao^*, Jichun Ye, and Xiaofeng Li^*. Enhanced photoelectrical response of hydrogenated amorphous silicon single-nanowire solar cells by front-opening crescent design.Nanoscale Research Letters2016, 11:233.

[106] Zhenhai Yang, Aixue Shang, Linling Qin, Yaohui Zhan, Cheng Zhang, Pingqi Gao, Jichun Ye, and Xiaofeng Li^*. Broadband and wide-angle light-harvesting by ultra-thin silicon solar cells with partially embedded dielectric spheres.Optics Letters2016, 41(7):1329−1332.

[107] Cheng Zhang,Kai Wu, Bo Ling, and Xiaofeng Li^*.Conformal TCO-semiconductor-metal nanowire array for narrowband and polarization-insensitive hot-electron photodetection application.Journal of Photonics for Energy2016, 6(4):042502.

[108] Jimu Yan^#, Shaolong Wu^#,*, Xiongfei Zhai, Xiang Gao, and Xiaofeng Li^*.Facile fabrication of wafer-scale, micro-spacing and high-aspect-ratio silicon microwire arrays.RSC Advances2016, 6:87486−87492.

[109] Suqiong Zhou, Zhenhai Yang, Pingqi Gao^*, Xiaofeng Li^*, Xi Yang, Dan Wang, Jian He, Zhiqin Ying and Jichun Ye^*.Wafer-scale integration of inverted nanopyramid arrays for advanced light trapping in crystalline silicon thin film solar cells.Nanoscale Research Letters2016, 11:194.

[110] Jian He, Zhenhai Yang, Peipei Liu, Sudong Wu, Pingqi Gao^*, Mei Wang, Suqiong Zhou, Xiaofeng Li^*, Hongtao Cao, and Jichun Ye^*.Enhanced electro-optical properties of nanocone/nanopillar dual-structured arrays for ultrathin silicon/organic hybrid solar cell applications.Advanced EnergyMaterials2016,6:1501793.(Inside Front Cover)

[111] Zhenhai Yang, Pingqi Gao^*, Cheng Zhang, Xiaofeng Li, and Jichun Ye^*. Scattering effect of the high-index dielectric nanospheres for high performance hydrogenated amorphous silicon thin-film solar cells.Scientific Reports2016, 6:30503.

Year 2015

[112] Xiongfei Zhai, Guoyang Cao, Shaolong Wu^*, Aixue Shang, Xiaofeng Li^*. Study on limiting efficiencies ofa-Si:H/μc-Si:H-based single-nanowire solar cellsunder single and tandem junction configurations.Applied Physics Letters2015,107:181106.

[113] Cheng Zhang, Zhenhai Yang, Aixue Shang, Shaolong Wu, Yaohui Zhan, and Xiaofeng Li^*.Improved optical absorption of silicon single-nanowire solar cells by off-axial core/shell design.Nano Energy2015, 17:233−240.

[114] Kai Wu, Yaohui Zhan, Cheng Zhang, Shaolong Wu, and Xiaofeng Li^*. Strong and highly asymmetrical optical absorption in conformal metal-semiconductor-metal grating system for plasmonic hot-electron photodetection application.Scientific Reports2015, 5:14304.

[115] Yaohui Zhan, Kai Wu, Cheng Zhang, Shaolong Wu, and Xiaofeng Li^*. Infrared hot-carrier photodetection based on planar perfect absorber.Optics Letters2015, 40(18):4261−4264.

[116] Kai Wu, Yaohui Zhan^*, Shaolong Wu, Jiajia Deng, and Xiaofeng Li^*. Surface-plasmon enhanced photodetection at communication band based on hot electrons.Journal of Applied Physics2015, 118:063101.

[117] Aixue Shang, Xiongfei Zhai, Cheng Zhang, Yaohui Zhan, Shaolong Wu, and Xiaofeng Li^*. Nanowire and nanohole silicon solar cells: a thorough optoelectronic evaluation.Progress in Photovoltaics: Research and Applications2015, 23:1734−1741.

[118] Xiaofeng Li^*, Yaohui Zhan and Chinhua Wang. Broadband enhancement of coaxial heterogeneous gallium arsenide single-nanowire solar cells.Progress in Photovoltaics: Research and Applications2015, 23:628−636.

[119] Zhenhai Yang^#, Xiaofeng Li^#,*, Dang Yuan Lei, Aixue Shang, and Shaolong Wu.Omnidirectional absorption enhancement of symmetry-broken crescent-deformed single-nanowire photovoltaic cells.Nano Energy2015, 13: 9−17.

[120] Zhenhai Yang, Xiaofeng Li^*, Shaolong Wu, Pingqi Gao, and Jichun Ye. High-efficiency photon capturing in ultrathin silicon solar cells with front nanobowl texture and truncated-nanopyramid reflector.Optics Letters2015, 40(6):1077−1080.

[121] Shaolong Wu, Cheng Zhang, Xiaofeng Li^*, and Yaohui Zhan. Proximity effect assisted absorption enhancement in thin film with locally clustered nanoholes.Optics Letters2015, 40(5):792‒795.

[122] Yaohui Zhan, Xiaofeng Li^*, Kai Wu, Shaolong Wu, and Jiajia Deng. Coaxial Ag/ZnO/Ag nanowire for highly sensitive hot-electron photodetection.Applied Physics Letters2015, 106:081109.

[123] Xiongfei Zhai, Shaolong Wu, Aixue Shang, and Xiaofeng Li^*.Limiting efficiency calculation of silicon single-nanowire solar cells with considering auger recombination.Applied Physics Letters2015, 106:063904.

[124] Aixue Shang and Xiaofeng Li^*. Carrier depletion and electrical optimization of gallium arsenide plasmonic solar cell with a rear metallic grating.Applied Physics Letters2015, 106:051107.

[125] Shaolong Wu, Cheng Zhang, Xiaofeng Li^*, Yaohui Zhan, and Chinhua Wang.Enhanced light trapping in a-Si:H/μc-Si:H tandem solar cells via nanopatterning top absorber and embedding wavelength-selective intermediate reflectors.IEEE J. Photovoltaics2015, 5(1):46‒54.

[126] Sheng Gan, Chuantong Cheng, Yaohui Zhan, Beiju Huang, Xuetao Gan, Shaojuan Li, Xiaofeng Li, Jianlin Zhao, Hongda Chen^*, and Qiaoliang Bao^*.A highly efficient thermo-optic microring modulator assisted by graphene.Nanoscale2015, 7:20249−20255.

[127] Xi Yang, Suqiong Zhou, Dan Wang, Jian He, Jun Zhou, Xiaofeng Li, Pingqi Gao^*, and Jichun Ye^*. Light trapping enhancement in a thin film with 2D conformal periodic hexagonal arrays.Nanoscale Research Letters2015, 10:284.

[128] Jing Cao, Chinhua Wang^*, Xiaofeng Li, Bing Cao, Yimin Lou. Highly efficient ultra-thin crystalline silicon solar cell with plasmonic cavities.International Journal of Nanotechnology2015, 12(10/11/12):769−781.

[129] W. L. Zhang^*, X. M. Wu, F. Wang, R. Ma, X. F. Li, and Y. J. Rao. Stark effect induced microcavity polariton solitons.Optics Express2015, 23(12):15762−15767.

Year 2014

[130] Guoyang Cao,Xiaofeng Li^*, Yaohui Zhan, Shaolong Wu, Aixue Shang, Cheng Zhang, Zhenhai Yang, and Xiongfei Zhai.Design of μc-Si:H/a-Si:H coaxial tandem single-nanowire solar cells considering photocurrent matching.Optics Express2014, 22(S7):A1761-A1767.

[131] Yaohui Zhan, Xiaofeng Li^*, Shaolong Wu, Ke Li, Zhenhai Yang, and Aixue Shang. Enhanced photoabsorption in front-tapered single-nanowire solar cells.Optics Letters2014, 39(19):5756-5759.

[132] Cheng Zhang, Xiaofeng Li^*,Aixue Shang, Shaolong Wu, Yaohui Zhan, and Zhenhai Yang. Designofdual-diameter nanoholes for efficient solar light harvesting.Nanoscale Research Letters2014, 9:481.

[133] Yaohui Zhan, Dang Yuan Lei^*, Xiaofeng Li^*, and Stefan A. Maier. Plasmonic Fano resonances in nanoholequadrumersfor ultra-sensitive refractive index sensing.Nanoscale2014, 6:4705-4715.

[134] Yaohui Zhan, Xiaofeng Li^*, Dang Yuan Lei, Shaolong Wu, Chinhua Wang, and Yao Li^*. Enhanced photoresponsivity of a germanium single-nanowire photodetector confined within a superwavelength metallic slit.ACS Photonics2014, 1(6):483-488.

[135] Ke Li, Xiaofeng Li^*, Dang Yuan Lei, Shaolong Wu, and Yaohui Zhan. Plasmon gap mode-assisted third-harmonic generation from metal film-coupled nanowires.Applied Physics Letters2014, 104:261105.

[136] Shaolong Wu, Xiaofeng Li^*, Yaohui Zhan, and Ke Li. Absorption enhancement of single silicon nanowire by tailoring rear metallic film for photovoltaic applications.Optics Letters2014, 39(4):817–820.

[137] Cheng Zhang, Xiaofeng Li^*,Aixue Shang, Yaohui Zhan, Zhenhai Yang, Shaolong Wu.Performance-improved thin-film a-Si:H/μc-Si:H tandem solar cells by two-dimensionally nanopatterning photoactive layer.Nanoscale Research Letters2014, 9:73.

[138] Shaolong Wu^*, Xiaofeng Li, Yaohui Zhan, Jianhua Deng, and Guo-an Cheng^*. Enhanced photoelectrochemical responses of silicon nanowire arrays through coating carbon shell.Journal of the Electrochemical Society2014, 161(4):H240-H243.

[139] Zhonghui Chen, Chinhua Wang^*, Fuyang Xu, Yimin Lou, Bing Cao, and Xiaofeng Li. Reflective plasmonic waveplates based on metal–insulator–metal subwavelength rectangular annular arrays.Photonics and Nanostructures - Fundamental and Applications2014, 12:189-198.

[140] Xinjiang Li, Xiaofeng Li, and Chinhua Wang^*. A new method for measuring wetness of flowing steam based on surface plasmon resonance.Nanoscale Research Letters2014, 9:18.

[141] Xin Luo, Xihua Zou^*, Xiaofeng Li, Wei Pan, Bin Luo, and Lianshan Yan. Plasmonic filter using metal-insulator-metal waveguides with phase shifts and its transmission characteristics.Plasmonics2014, 9:887-892.

Year 2013

[142] Xiaofeng Li^*, Nicholas P. Hylton, Vincenzo Giannini, Kan-Hua Lee, Ned J. Ekins-Daukes, and Stefan A. Maier.Multi-dimensional modelling of solar cells with electromagnetic and carrier transport calculations.Progress in Photovoltaics: Research and Applications2013, 21(1):109–120.

[143] Xiaofeng Li^*and Yaohui Zhan. Enhanced external quantum efficiency in rectangular single nanowire solar cells.Applied Physics Letters2013, 102(2):021101.

[144] Zhenhai Yang, Aixue Shang, Yaohui Zhan, Cheng Zhang, and Xiaofeng Li^*. Ultra-broadband performance enhancement of thin-film amorphous silicon solar cells with conformal zig-zag configuration.Optics Letters2013, 38(23):5071–5074.

[145] Xiaofeng Li^*, Cheng Zhang, Zhenhai Yang, and Aixue Shang. Broadband, polarization-insensitive and wide-angle absorption enhancement of a-Si:H/μc-Si:H tandem solar cells by nanopatterning a-Si:H layer.Optics Express2013, 21(S4):A677–A686.

[146] Yaohui Zhan, Xiaofeng Li^*, and Yao Li^*.Numerical simulation of light-trapping and photoelectric conversion in single nanowire silicon solar cells.IEEE J. Selected Topics in Quantum Electronics2013, 19:4000208.

[147] N. P. Hylton, X. F. Li, V. Giannini, K-H. Lee, N. J. Ekins-Daukes, J. Loo, D. Vercruysse, P. Van Dorpe, H. Sodabanlu, M. Sugiyama, and S. A. Maier. Loss mitigation in plasmonic solar cells: aluminum nanoparticles for broadband photocurrent enhancements in GaAs photodiodes.Scientific Reports2013, 3:2874.

[148] Xin Luo, Xihua Zou^*, Xiaofeng Li, Zhi Zhou, Wei Pan, Lianshan Yan, and Kunhua Wen. High-uniformity multichannel plasmonic filter using linearly lengthened insulators in metal-insulator-metal waveguide.Optics Letters2013, 38(9):1585–1587.

[149] Yanqin Song, Chinhua Wang^*, Yimin Lou, Bing Cao, and Xiaofeng Li. Near-perfect absorber with ultrawide bandwidth in infrared region using a periodically chirped structure.Optics Communications2013, 305:212–216.

[150] Zhonghui Chen, Chinhua Wang^*, Yimin Lou, Bing Cao, and Xiaofeng Li. Quarter-wave plate with subwavelength rectangular annular arrays.Optics Communications2013, 297:198–203.

Year 2011

[151] Xiaofeng Li^*, Nicholas P. Hylton, Vincenzo Giannini, Kan-Hua Lee, Ned J. Ekins-Daukes, and Stefan A. Maier.Bridging electromagnetic and carrier transport calculations for three-dimensional modelling of plasmonic solar cells.Optics Express2011, 19(S4):A888–A896.

[152] H. K. Liang, S. F. Yu^*, X. F. Li, S. Z. Ma, and H. Y. Yang. An index-guided ZnO random laser array.IEEE Photonics Technology Letters2011, 23(8):522–524.

[153] S. H. Tsang, S. F. Yu^*, X. F. Li, H. Y. Yang, and H. K. Liang. Observation of Tamm plasmon polaritons in visible regime from ZnO/Al₂O₃distributed Bragg reflector – Ag interface.Optics Communications2011, 284(7):1890–1892.

[154] R. G. Mote, S. F. Yu^*, A. Kumar, W. Zhou, and X. F. Li. Experimental demonstration of near-field focusing of a phase micro-Fresnel zone plate (FZP) under linearly polarized illumination.Applied Physics B2011, 102:95–100.

Year 2010

[155] X. F. Li^*and S. F. Yu. Extremely high sensitive plasmonic refractive index sensors based on metallic grating.Plasmonics2010, 5(4):389–394.

[156] X. F. Li^*and S. F. Yu. Design of low-threshold compact Au-nanoparticle lasers.Optics Letters2010, 35(15):2535–2537.

[157] X. F. Li^*and S. F. Yu. Long-wavelength optical transmission of extremely narrow slits via hybrid surface-plasmon and Fabry-Pérot modes.J. Applied Physics, 2010, 108(1):213302.

[158] X. F. Li^*and S. F. Yu. Diffraction characteristics of concentric circular metal grating operating within terahertz regime.IEEE J. Quantum Electronics2010, 46(6):898–905.

[159] X. F. Li^*, S. F. Yu, and A. Kumar. Excitation and optimization modeling of surface plasmon polaritons in a concentric circular metallic grating film.Plasmonics2010, 5(1):69–74.

Year 2009

[160] X. F. Li^*, S. F. Yu, and A. Kumar. A surface-emitting distributed-feedback plasmonic laser.Applied Physics Letters2009, 95(14):141114.

[161] X. F. Li^*and S. F. Yu. Modal characteristics of terahertz surface-emitting DFB lasers with a second-order concentric circular metal grating.J. Applied Physics2009, 106(5):053103.

[162] Ashwani Kumar, S. F. Yu^*, and X. F. Li. Design and analysis of a surface plasmon polariton modulator using electro-optic effect.Applied Optics2009, 48(35):6600–6605.

[163] Ashwani Kumar, S. F. Yu^*, and X. F. Li. Random laser action in dielectric-metal-dielectric surface plasmon waveguides.Applied Physics Letters2009, 95(23):231114.

[164] R. G. Mote, S. F. Yu^*, W. Zhou, and X. F. Li. Subwavelength focusing behavior of high numerical-aperture phase Fresnel zone plates under various polarization states.Applied Physics Letters2009, 95(19):191113.

[165] S. H. Tsang, S. F. Yu^*, H. Y. Yang, H. K. Liang, and X. F. Li. ZnO/ZnMgO multiple quantum wells ridge waveguide lasers.IEEE Photonics Technology Letters2009, 21(21):1624–1626.

[166] S. H. Tsang, S. F. Yu^*, S. P. Lau, H. Y. Yang, and X. F. Li. Suppression of random lasing modes in polycrystalline ZnO thin-film by using distributed Bragg reflector.IEEE Photonics Technology Letters2009, 21(8):549–551.

[167] R. G. Mote, S. F. Yu^*, W. Zhou, and X. F. Li. Design and analysis of two-dimensional high-index-contrast grating surface-emitting lasers.Optics Express2009, 17(1):260–265.

Year 2008

[168] X. F. Li^*and S. F. Yu. Modeling of Rabi splitting in quantum well microcavities using time-dependent transfer matrix method.Optics Express2008, 16(23):19285–19290.

[169] Ashwani Kumar, S. F. Yu^*, X. F. Li, and S. P. Lau. Surface plasmonic lasing via the amplification of coupled surface plasmon waves inside dielectric-metal-dielectric waveguides.Optics Express2008, 16(20):16113–16123.

[170] X. F. Li^*and S. F. Yu. Multiple-mode behavior of circular-grating-coupled distributed feedback lasers.J. Lightwave Technology2008, 26(19):3345–3354.

[171] X. F. Li^*and S. F. Yu. Static and dynamic modeling of circular grating-coupled distributed feedback lasers.IEEE J. Quantum Electronics2008, 44(8):770–776.

[172] X. F. Li^*, S. H. Tsang, S. F. Yu, and W. J. Fan.Analysis and design of antiresonant reflecting optical waveguide vertical-cavity surface-emitting lasers for above-threshold operation.J. Lightwave Technology2008, 26(13):1935–1942.

[173] X. F. Li^*, S. F. Yu, and W. J. Fan. Design of stable single-mode chaotic light source using anti-resonant reflecting optical waveguide vertical-cavity surface-emitting lasers.IEEE J. Quantum Electronics2008, 44(4):338–345.

[174] W. L. Zhang^*, W. Pan, B. Luo, X. F. Li, X. H. Zou, and M. Y. Wang. Theoretical study on phase conjugation in weakly injected vertical-cavity surface-emitting lasers.Chinese Physics B2008, 17(5):1821–1825.

[175] W. L. Zhang^*, W. Pan, B. Luo, X. F. Li, X. H. Zou, and M. Y. Wang. Polarization-resolved dynamics of asymmetrically coupled vertical-cavity surface-emitting lasers.J. Optical Society of America B2008, 25(2):153–158.

Year 2007

[176] X. F. Li^*, W. Pan, B. Luo, D. Ma, W. L. Zhang.Nonlinear dynamics and localized synchronization in mutually coupled VCSELs.Optics & Laser Technology2007, 39(4):875–880.

[177] W. L. Zhang^*, W. Pan, B. Luo, X. F. Li, X. H. Zou, and M. Y. Wang. Theoretical study on polarization dynamics of VCSELs with negative optoelectronic feedback.Applied Optics2007, 46(29):7262–7266.

[178] W. L. Zhang^*, W. Pan, B. Luo, X. F. Li, X. H. Zou, and M. Y. Wang. Influence of polarization-selected mutual injection on the polarization-switching dynamics of vertical-cavity surface-emitting lasers.J. Optical Society of America B2007, 24(9):2472–2478.

[179] W. L. Zhang^*, W. Pan, B. Luo, X. F. Li, X. H. Zou, and M. Y. Wang. Polarization switching and synchronization of mutually coupled vertical-cavity surface-emitting semiconductor lasers.Chinese Physics B2007, 16(7):1996–2002.

[180] W. L. Zhang^*, W. Pan, B. Luo, X. F. Li, X. H. Zou, and M. Y. Wang. Polarization switching of mutually coupled vertical-cavity surface-emitting.J. Optical Society of America B2007, 24(6):1276–1282.

Year 2006

[181] X. F. Li^*, W. Pan, B. Luo, D. Ma.Chaos synchronization and communication of cascade-coupled semiconductor lasers.J. Lightwave Technology2006, 24(12):4936–4945.

[182] X. F. Li^*, W. Pan, B. Luo, D. Ma.Control of nonlinear dynamics in external-cavity VCSELs with delayed negative optoelectronic feedback.Chaos, Solitons & Fractals2006, 30(4):1004–1011.

[183] X. F. Li^*, W. Pan, B. Luo, D. Ma.Mismatch robustness and security of chaotic optical communications based on injection-locking chaos synchronization.IEEE J. Quantum Electronics2006, 42(9):953–960.

[184] X. F. Li^*, W. Pan, B. Luo, D. Ma.Multi-transverse-mode dynamics of vertical-cavity surface-emitting lasers with external optical injection.J. Optical Society of America B2006, 23(7):1292–1301.

[185] X. F. Li^*, W. Pan, D. Ma, B. Luo.Chaos synchronization of unidirectionally injected VCSELs with global and mode-selective coupling.Optics Express2006, 14(8):3138–3151.

[186] X. F. Li^*, W. Pan, B. Luo, D. Ma.Effects of unwanted feedback on synchronized chaotic optical communications.Applied Optics2006, 45(11):2510–2520.

[187] X. F. Li^*, W. Pan, B. Luo, D. Ma, G. Deng.Static and dynamic characteristics of VCSELs with polarisation-selective optical feedback.IEE Proc.-Optoelectronics2006, 153(2):67–74.

[188] X. F. Li^*, W. Pan, B. Luo, D. Ma, Y. Wang, N. H. Li.Nonlinear dynamic behaviors of an optically injected vertical-cavity surface-emitting laser.Chaos, Solitons & Fractals2006, 27(5):1387–1394.

[189] X. F. Li^*, W. Pan, B. Luo, D. Ma.Nonlinear dynamics of two mutually injected external-cavity semiconductor lasers.Semiconductor Science & Technology2006, 21(1):25–34.

Year 2005

[190] X. F. Li^*, W. Pan, B. Luo, D. Ma, N. H. Li, Y. Wang. Suppressing nonlinear dynamics induced by external optical feedback in vertical-cavity surface-emitting lasers.Optics & Laser Technology2005, 37(6):438–443.

[191] X. F. Li^*, W. Pan, B. Luo, D. Ma, G. Deng.Theoretical analysis of multi-transverse-mode characteristics of vertical-cavity surface-emitting lasers.Semiconductor Science & Technology2005, 20(6):505–513.

Books Patents

There are several vacancies available in our group each year.

The vacancies in photonics and related devices include:

1) The graduated students

2) The postdoc researchers

3) Faculties in various levels

4) The international visiting students or scholars

Please contact:

Professor Xiaofeng LI

Email:xfli@suda.edu.cn