陆明 -亚博vip888

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。

部分指导的研究生就业：

中科院上海技术物理所，百人计划获得者

中电55所，军科委项目首席专家

中科院西安光机所

合肥工业大学机械工程系

上海集成电路研发中心

汇添富基金管理有限公司

创智慧源董事长及多家公司创始人

• 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

• 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

• 本科课程：《大学物理》

• 研究生课程：《专业英语》 《纳米光子学》

    已在国内外学术刊物上发表sci论文100余篇，授权发明专利8项，参与编写英语学术专著1部（美国nova科学出版社）。完成多份国防报告。

近年发表文章：

1.  achieving high brightness of si led via a field effect approach，appl. phys. lett. 104, 061105(2014)

2. surface plasmons on ag clusters induced via ultrasonic and thermal treatments and their enhancement of si light emission，physica e 64, 63-67(2014)

3.  mass production of si quantum dots for c-si solar cell efficiency improvement，mater. lett. 133, 80-82(2014)

4.  enhancing the brightness of si nanocrystal light emitting device with electro-excited surface plasmons，nanotechnology 25, 355203(2014)

5.  enhancing optical gains in si nanocrystals with hydrogenation and cerium doping，j. appl. phys. 116, 043512(2014)

6.  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)

7. a synergetic effect of surface texture and field passivations on improving si solar cell performance，physica e 71, 96-100(2015)

8.  enhancing photocatalysis in srtio₃ by using ag nanoparticles: a two-step excitation model for surface plasmon-enhanced photocatalysis，j. chem. phys. 143, 084706(2015)

9.  white light emissions and optical gains from a si nanocrystal thin film，nanotechnology 26, 475203(2015)

10. a synergetic application of surface plasmon and field effect to improve si solar cell performance，nanotechnology 27, 145203(2016)

11.  a porous si emitter crystalline-si solar cell with 18.97% efficiency s，nanotechnology 27,  425207(2016)

12. high fill factors of si solar cells achieved by using an inverse connection between mos and pn junctions，nanoscale res. lett. 11, 453(2016)

13.  a synergetic effect of surface plasmon and ammoniation on the enhanced photocatalytic activity of zno nanorods，rsc advances 6, 97808-97817(2016)

14. light emissions from a si crystalline thin film prepared by hsq，physica e 89, 57-60(2017)

15. enhancing the ultraviolet-visible-near infrared photovoltaic responses of crystalline-silicon solar cell by using aluminum nanoparticles，physica e 94, 174-177(2017)

16.  an investigation on a crystalline-silicon solar cell with black silicon layer at the rear，nanoscale research letters, 12, 623(2017)

17.  an all-silicon laser based on silicon nanocrystals with high optical gains，science bulletin 63(2)75-77 (2018)

18.  a synergetic effect of ytterbium-doping and ammoniation on enhancing uv and visible photocatalytic activities of tio2，chemical physics letters, 2018, 64c: 53-59.

19.  black silicon schottky photodetector in sub-bandgap near-infrared regime，optics express 27(3),  3161-3168(2019)

20.  emission characteristics and wavelength tunability of all-silicon distributed feedback lasers，ieee jstqe 26(2), 1500107(1-7)(2020)

21.  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)）

22. high-pressure hydrogenation induced light emission enhancement of si nanocrystals，opt. express 28， 23320-23328（2020）

23. improving the performance of crystalline si solar cell by high-pressure hydrogenation，chinese phys. b vol. 29, no. 11 (2020) 118801

24. high-pressure ar passivation to enhance the photoluminescence of si nanocrystals, physics e 131, 114680(2021).

25. 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)）

26. 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). 

27. dispersed freestanding silicon nanocrystals for si white light-emitting diode, chemical physics letters 785, 139155(2021). 

28. a synergistic approach of interface engineering to improve the performance of silicon nanocrystal light-emitting diode, vacuum 197, 110822(2022).

29. observation of waveguide fabry-perot lasing in highly efficient si nanocrystals, results in physics 34, 105336 (2022).

30. 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.

31. 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.