陆明 - 复旦大学 - 信息科学与工程学院

个人简介

学习工作经历复旦大学物理系本科学生复旦大学物理系硕士研究生复旦大学物理系博士研究生奥地利Graz大学博士后博士后美国Houston大学助理研究员获奖情况中国工程物理研究院预研项目二等奖 1999----上海市高校优秀青年教师称号 2003----教育部优秀青年教师基金

研究领域

主要研究方向为硅光（硅基光电子）技术，包括全硅激光器、黑硅太阳电池、全硅红外探测器、红外太阳电池等。研究工作被国内外30多家主流和专业媒体的报道。是全硅激光器、全硅WLED和高效黑硅太阳电池的主要发明人。在表面等离激元、场钝化效应、光致发光增强、光致发光转换、硅表面纳米织构、硅的全太阳光谱强吸收、单晶硅电池制备、金属离子扩散行为等方面有着多年研究积累。曾负责及承担多项国防和国家自然科学基金项目、973项目子课题、上海市科委重点项目。

近期论文

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Achieving high brightness of Si LED via a field effect approach，Appl. Phys. Lett. 104, 061105(2014) Surface plasmons on Ag clusters induced via ultrasonic and thermal treatments and their enhancement of Si light emission，Physica E 64, 63-67(2014) Mass production of Si quantum dots for c-Si solar cell efficiency improvement，Mater. Lett. 133, 80-82(2014) Enhancing the brightness of Si nanocrystal light emitting device with electro-excited surface plasmons，Nanotechnology 25, 355203(2014) Enhancing optical gains in Si nanocrystals with hydrogenation and cerium doping，J. Appl. Phys. 116, 043512(2014) Effects of crystallographic surface and co-sputtered atom on the growth of ion-sputter induced Si nanocone arrays，Appl. Phys. A 119, 1033-1038(2015) A synergetic effect of surface texture and field passivations on improving Si solar cell performance，Physica E 71, 96-100(2015) Enhancing photocatalysis in SrTiO3 by using Ag nanoparticles: A two-step excitation model for surface plasmon-enhanced photocatalysis，J. Chem. Phys. 143, 084706(2015) White light emissions and optical gains from a Si nanocrystal thin film，Nanotechnology 26, 475203(2015) A synergetic application of surface plasmon and field effect to improve Si solar cell performance，Nanotechnology 27, 145203(2016) A porous Si emitter crystalline-Si solar cell with 18.97% efficiency s，Nanotechnology 27, 425207(2016) High Fill Factors of Si Solar Cells Achieved by Using an Inverse Connection Between MOS and PN Junctions，Nanoscale Res. Lett. 11, 453(2016) A Synergetic Effect of Surface Plasmon and Ammoniation on the Enhanced Photocatalytic Activity of ZnO Nanorods，RSC Advances 6, 97808-97817(2016) Light emissions from a Si crystalline thin film prepared by HSQ，Physica E 89, 57-60(2017) Enhancing the ultraviolet-visible-near infrared photovoltaic responses of crystalline-silicon solar cell by using aluminum nanoparticles，Physica E 94, 174-177(2017) An Investigation on a Crystalline-Silicon Solar Cell with Black Silicon Layer at the Rear，Nanoscale Research Letters, 12, 623(2017) An all-silicon laser based on silicon nanocrystals with high optical gains，Science Bulletin 63(2)75-77 (2018) A Synergetic Effect of Ytterbium-doping and Ammoniation on Enhancing UV and visible Photocatalytic Activities of TiO2，Chemical Physics Letters, 2018, 64C: 53-59. Black silicon Schottky photodetector in sub-bandgap near-infrared regime，Optics Express 27(3), 3161-3168(2019) Emission characteristics and wavelength tunability of all-silicon distributed feedback lasers，IEEE JSTQE 26(2), 1500107(1-7)(2020) All-Inorganic Silicon White Light-Emitting Device with an External Quantum Efficiency of 1.0%，Opt. Express 28, 194(2020). （该工作被Laser Focus World作专题报导，J. Wallace, Laser Focus World 56, 31(2020)） High-pressure hydrogenation induced light emission enhancement of Si nanocrystals，Opt. Express 28， 23320-23328（2020） Improving the performance of crystalline Si solar cell by high-pressure hydrogenation，Chinese Phys. B Vol. 29, No. 11 (2020) 118801 High-pressure Ar passivation to enhance the photoluminescence of Si nanocrystals, Physics E 131, 114680(2021). High brightness silicon nanocrystal white light-emitting diode with luminance of 2060 cd/m2, Optics Express 29, 34126-34134(2021). （该工作被Semiconductor Today作专题报导, M. Cooke, Semiconductor Today, October (2021)。它是当时最高亮度的硅LED——此结论见：L. Pavesi, “Thirty Years in Silicon Photonics: A Personal View”, Frontiers in Physics 9, 786028 (December 2021)） Achieving high-responsivity near-infrared detection at room temperature by nano-Schottky junction arrays via a black silicon/platinum contact approach, Photonics Research 9, 1324-1329(2021). Dispersed freestanding silicon nanocrystals for Si white light-emitting diode, Chemical Physics Letters 785, 139155(2021). A synergistic approach of interface engineering to improve the performance of silicon nanocrystal light-emitting diode, Vacuum 197, 110822(2022). Observation of waveguide Fabry-Perot lasing in highly efficient Si nanocrystals, Results in Physics 34, 105336 (2022). Sub-bandgap near-infrared photovoltaic response in Au/Al2O3/n-Si metal–insulator–semiconductor structure by plasmon-enhanced internal photoemission, Discover Nano, 18(2023): 33. A Silicon Sub-Bandgap Near-Infrared Photodetector with High Detectivity Based on Textured Si/Au Nanoparticle Schottky Junctions Covered with Graphene Film, Sensors, 23(2023): 6184.