王丹青，复旦光科系青年研究员，博士生导师，国家海外高层次青年人才项目、复旦新工科人才计划入选者。博士毕业于美国西北大学，师从美国科学院院士Teri Odom和George Schatz教授，后于美国加州大学伯克利分校任米勒研究员(合作导师:吴军桥)，以及德国马普所光科学研究所任博士后研究员(合作导师:Vahid Sandoghdar)。

主要研究领域为微纳光学，集成器件和量子光学。迄今共发表SCI学术论文28余篇，第一和共同第一作者文章包括Nature Nanotechnology, Nature Materials, Nano Letters, Chemical Reviews, Accounts of Chemical Research等国际高影响力期刊，谷歌总引用2700余次，h指数22。获得光学新星奖，米勒研究奖学金, 美国材料学会研究生奖，国家优秀自费留学生奖学金等奖项。

个人网页：https://danqing-wang.github.io/

Google Scholar：https://scholar.google.com/citations?user=XbzEcqMAAAAJ&hl=en

ORCID：https://orcid.org/0000-0002-7369-1944

研究方向包括且不限于:

结构性纳米材料的光学特异行为

基于微纳光腔的光子集成策略

新型激光反馈机制

室温下的量子光子学研究

研究组常年招收博士后，以及计划每年招收数名硕士和博士研究生，欢迎物理, 光学, 材料, 电子等专业背景的申请者报名!

(详情见：https://hr.fudan.edu.cn/c7/46/c4841a706374/page.htm)

2023.11 分会主席 International Workshop on Quantum Materials for 2D Photonics & Optoelectronics, Singapore

2023.06 共同主席 Gordon Research Seminar (Lasers in Micro, Nano and Bio Systems), USA

Physical Review Letters、ACS Photonics、Optica、Optics Express等期刊独立审稿人

2023    高层次青年人才项目（海外）

2023    复旦大学新工科人才基金

2023    Rising Stars of Light (3 awardees globally, before faculty track)

2022    Rising Stars in EECS, USA

2021    Forbes 30 Under 30 in Science, USA

2019    Miller Research Fellowship, University of California, Berkeley  

2018    Material Research Society Graduate Student Award, Silver Award

2018    Excellent Poster Award, Gordon Research Conference on Lasers in Micro, Nano and Bio Systems

2018    Honorable Mention, International Precious Metals Institute Student Award

2018    国家优秀自费留学生奖学金   

2017    Outstanding Research Award, International Institute for Nanotechnology, Northwestern University

2013    国家大学生创新性实验计划国家级优秀奖

2024 - 至今   复旦大学光科学与工程系，青年研究员

2023 - 2024  德国马普所光科学研究所，博士后研究员

2019 - 2023  美国加州大学伯克利分校材料系，米勒研究员

2013 - 2019  美国西北大学，应用物理，博士研究生

2009 - 2013  南京大学，物理，本科生

Patent

1.   Hong, J.; Wu, J.; Wang, D. "Method and Apparatus of Hybrid Integrated Photonics Devices" (US Patent no. 20240184039, June 6, 2024)

First and co-first author

1.   Wang, D.*; Yang, A. “Miniaturized optics from structured nanoscale cavities,” Progress in Quantum Electronics 94, 100507 (2024) (*corresponding author)

2.   Wang, D.; Hu, J.; Schatz, G.C.; Odom, T.W. “Superlattice Surface Lattice Resonances in Plasmonic Nanoparticle Arrays with Patterned Dielectrics,” Journal of Physical Chemistry Letters 14, 38, 8525–8530 (2023)

3.   Wang, D.*; Dong, K.; Li, J.; Grigoropoulos, C.; Yao, J.; Hong, J.; Wu, J.* “Low-loss, Geometry-invariant Optical Waveguides with Near-zero-index Materials,” Nanophotonics 11, 21, 4747–4753 (2022) (*corresponding author)

4.   Wang, D.; Bourgeois, M.R.; Guan, J.; Fumani, A.K.; Schatz, G.C.; Odom, T.W. “Lasing from Finite Plasmonic Nanoparticle Lattices,” ACS Photonics 7, 630-636 (2020)

5.   Fernandez-Bravo, A.⁺; Wang, D.⁺; Barnard, E.S.; Teitelboim, A.; Tajon, C.; Guan, J.; Schatz, G.C.; Cohen, B.E.; Chan, E.; Schuck, P.J.; Odom, T.W. “Ultralow-threshold, Continuous-wave Upconverting Lasing from Subwavelength Plasmons,” Nature Materials 18, 1172–1176 (2019) (⁺equal contribution)

6.   Wang, D.; Guan, J.; Hu, J.; Bourgeois, M.R.; Odom, T.W. “Manipulating Light-matter Interactions in Plasmonic Nanoparticle Lattices,” Accounts of Chemical Research 52, 2997-3007 (2019)

7.   Wang, D.; Bourgeois, M.R.; Lee, W.; Li, R.; Trivedi, D.; Knudson, M.P.; Wang, W.; Schatz, G.C.; Odom, T.W. “Stretchable Nanolasing from Hybrid Quadrupole Plasmons,” Nano Letters 18, 4549–4555 (2018)

8.   Wang, D.; Yang, A.; Wang. W.; Hua, Y.; Schaller, R.D.; Schatz, G.C.; Odom, T.W. “Band-edge Engineering for Controlled Multi-modal Nanolasing in Plasmonic Superlattices,” Nature Nanotechnology 12, 889 (2017)

9. Wang, D.; Wang. W.; Knudson, M.P.; Schatz, G.C.; Odom, T.W. “Structural Engineering in   Plasmon Nanolasers,” Chemical Reviews 118, 2865–2881 (2017)

10. Tran, T.T. ⁺; Wang, D.⁺; Xu, Z-Q.⁺; Yang, A.; Toth, M.; Odom, T.W.; Aharonovich, I. “Deterministic Coupling of Quantum Emitters in 2D Materials to Plasmonic Nanocavity Arrays,” Nano Letters 17, 2634-2639 (2017) (⁺equal contribution)

11. Wang, D.; Yang, A.; Hryn, A.J.; Schatz, G.C.; Odom, T.W. “Superlattice Plasmons in Hierarchical Au Nanoparticle Arrays,” ACS Photonics 2, 1789 (2015)

Co-author

12. Lin, Y.; Fan, L.; Jiang, M.; Wang, D.; He J.; Fu, Y.; Wang, J.; Zhang, X. “Ultrafast Dynamics of Strong Near-Field Coupled Localized and Delocalized Surface Plasmons,” Advanced Optical Materials, 2400109 (2024)

13. Dong, K.; Zhang, T.; Li, J.; Wang, Q.; Yang, F.; Rho, Y.; Wang, D.; Grigoropoulos, C.P.; Wu, J.; Yao J. “Flat bands in magic-angle bilayer photonic crystals at small twists,” Phys. Rev. Lett. 126, 223601 (2021)

14. Guan, J.; Sagar, L.K.; Li, R.; Wang, D.; Bappi, G; Wang, W.; Watkins, N.; Bourgeois, M.R.; Levina, L.; Fan, F.; Hoogland, S.; Voznyy, O.; Martins, J.; Schaller, R.D.; Schatz, G.C.; Sargent, E.H.; Odom, T.W. “Quantum dot-plasmon lasing with controlled polarization patterns,” ACS Nano 14, 3426–3433 (2020)

15. Guan, J.; Sagar, L.K.; Li, R.; Wang, D.; Bappi, G; Watkins, N.; Bourgeois, M.R.; Levina, L.; Fan, F.; Hoogland, S.; Voznyy, O.; Martins, J.; Schaller, R.D.; Schatz, G.C.; Sargent, E.H.; Odom, T.W. “Engineering Directionality in Quantum Dot Shell Lasing Using Plasmonic Lattices,” Nano Letters 20, 1468-1474 (2020)

16. Lin, Y.; Wang, D.; Hu, J.; Liu, J.; Wang, W.; Schaller, R.D.; Odom, T.W. “Engineering Symmetry-breaking Nanocrescent Arrays for Nanolasing,” Adv. Funct. Mater. 1904157 (2019)

17. Hu, J.; Wang, D.; Bhowmik, D.; Liu, T.; Deng, S.; Knudson, M.P.; Ao, X.; Odom, T.W. “Lattice-Resonance Metalenses for Fully Reconfigurable Imaging,” ACS Nano 13, 4613-4620 (2019)

18. Ao, X.; Wang, D.; Odom, T.W. “Enhanced Fields in Mirror-backed Low-Index Dielectric Structures,” ACS Photonics 6, 2612-2617 (2019)

19. Li, R.; Wang, D.; Guan, J.; Wang, W.; Ao, X.; Schatz, G.C.; Schaller, R.C.; Odom, T.W. “Plasmon nanolasing with aluminum nanoparticle arrays,” J. Opt. Soc. Am. B 36, 104-111 (2019)

20. Liu, J.; Wang, W.; Wang, D.; Hu, J.; Ding, W.; Schaller, R.D.; Schatz, G.C.; Odom, T.W. “Spatially Defined Molecular Emitters Coupled to Plasmonic Nanoparticles,” Proc. Natl. Acad. Sci. 116, 5925-5930 (2019)

21. Knudson, M.P.; Li, R.; Wang, D.; Wang, W.; Schaller, R.D.; Odom, T.W. “Polarization-Dependent Lasing Behavior from Low-Symmetry Nanocavity Arrays,” ACS Nano 13, 7435-7441 (2019)

22. Cherqui, C.; Bourgeois, M.R.; Wang, D.; Schatz, G.C. “Plasmonic Surface Lattice Resonances: Theory and Computation,” Accounts of Chemical Research 52, 2548-2558 (2019)

23. Li, R.; Bourgeois, M.R.; Cherqui, C.; Guan, J.; Wang, D.; Hu, J.; Schaller, R.D.; Schatz, G.C.; Odom, T.W. “Hierarchical Hybridization in Plasmonic Honeycomb Lattices,” Nano Letters 19, 6435-6441 (2019)

24. Hooper, D. C.; Kuppe, C.; Wang, D.; Wang, W.; Guan, J.; Odom, T.W.; Valev, V.K. “Second harmonic spectroscopy of surface lattice resonances,” Nano Letters 19, 165-172 (2018)

25. Wang, D.; Wang, W.; Odom, T.W. et al. “Roadmap on Plasmonics: Nanoarray Lasing Spasers,” Journal of Optics 20, 043001 (2018)

26. Trivedi, D.; Wang, D.; Odom, T.W.; Schatz, G.C. “Model for Describing Plasmonic Nanolasers Using Maxwell-Liouville Equations with Finite-difference Time-domain Calculations,” Phys. Rev. A. 96, 053825 (2017)

27. Yang, A.; Wang, D.; Wang, W.; Odom, T. W. “Coherent Light Sources at the Nanoscale,” Annu. Rev. Phys. Chem. 68, 83-99 (2017)

28. Wang, S.; Wang, D.; Hu, X.; Li, T.; Zhu, S. “Compact Surface Plasmon Amplifier in Nonlinear Hybrid Waveguide,” Chinese Physics B 25, 7 (2016)