王绍军 教授

王绍军，苏州大学光电科学与工程学院教授和博士生导师、现代光学技术教育部重点实验室副主任、光电学院第三届学术委员会委员。自2016年获博士学位以来，长期致力于“共振纳米光子学”前沿领域，以等离激元和全介电超表面为核心平台，发展水浮法无损转移工艺和微区光谱表征技术，深入探索基于非局域晶格共振效应的光子新机制，用于高效光产生、高灵敏光传感及多维光探测等方面。至今发表学术论文40余篇，其中以第一/通讯作者在Nat. Commun.、Nano Lett.、Fundam. Res.、Laser & Photonics Rev.、ACS Photonics等期刊上发表SCI论文20篇；研究成果被Science、Nat. Photon.等引用2000余次，单篇最高引用超300次，H指数22。先后主持国家自然科学基金、江苏省自然科学基金等科研项目6项。受邀做国际会议特邀报告10余次；担任《激光与光电子学进展》第三、四届青年编委、中国光学工程学会光与物质相互作用专委会委员，以及IEEE IPC、META、微纳光学创新论坛等多个国内外重要会议专题组委；为NC、SA、Light、ACS Nano、ACS Photon.、AM、AFM等学术期刊审稿。指导的学生获中国科协青年人才托举工程、江苏省优秀硕士学位论文、中国激光杂志社首届“青衿奖”提名奖、䇹政学者等多项荣誉。

代表性论著

[1]Yiheng Zhai, Chaojie Xu, Zhenghe Zhang, Peng Li, Shunsuke Murai, Jaime Gómez Rivas, Xiaofeng Li, and Shaojun Wang, Efficient Redirection of Trapped Broad-Band Fluorescence from Substrates into Free Space Using c-Si Metasurfaces. Nano Letters, 2024, 24: 11311.

[2]Zhenghe Zhang, Chaojie Xu, Chen Liu, Man Lang, Yuehao Zhang, 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 Letters, 2023, 23: 7584.

[3]Zhenghe Zhang, Pengbo Liu, Wanli Lu, Ping Bai, Bingchang Zhang, Zefeng Chen, Stefan A.Maier, Jaime Gómez Rivas, Shaojun Wang, and Xiaofeng Li. High-Q Collective Mie Resonances in Monocrystalline Silicon Nanoantenna Arrays for the Visible Light. Fundamental Research, 2023, 3: 823. (Published online:2022-06)

[4]Shaojun Wang, Quynh Le-Van, Thibault Peyronel, Mohammad Ramezani, Niels Van Hoof, Tobias G. Tiecke, and Jaime Gómez Rivas, Plasmonic Nanoantenna Arrays as Efficient Etendue Reducers for Optical Detection, ACS Photonics, 2018，6: 2478.

[5]Shaojun Wang, Strong Light-Molecule Coupling: Routes to New Hybrid Materials, Ph.D. thesis, Defended on 2015 Sep 11.

Resonant Metasurfaces

2020年入职苏大以来的研究工作：

[1]Z. Zhang, C. Xu, X. Huang, F. Yang, Z. Chen, M. Li, X. Liu, G. Li, Y. Song, X. Li, and S. Wang, Directional and Polarization-Encoded Emission Via Rotational Displacement in Nonlocal Metasurfaces, Laser & Photonics Rev. e71354 (2026) 

Research Spotlight: we introduce a rotatable diatomic-lattice metasurface that maximizes Q-factor, emitter-field overlap, and geometric-phase control. Rotating eccentric nanodisks tunes linear polarization with stable spectra; geometric-phase supercells yield directional circular polarized emission.

[2]Q. Wang, H. Luo, C. Ma, B. Zhang, C. Ji, Q. Yu, G. Chai, Y. Li, C. Li, S. Wang, X. Gan, K. Liu, J. Zhao, and F. Xiao, "Unidirectional Giant Exciton Emission into a Photonic Waveguide", Phys. Rev. Lett. 135: 146905 (2025)

Research Spotlight: we demonstrate unidirectional, strongly Purcell-enhanced exciton emission from ultrathin InSe by embedding it in an asymmetric Au nanocube dimer-on-mirror nanocavity that launches light efficiently into an on-chip Si nanowire waveguide.

[3]C. Wang, S. Li, Y. Chen, Q. Zhou, J. Luo, S. Wang, L. Gao, and Y. Xu, "Dual-resonance metagrating for enhancing or annihilating third-harmonic generation at terahertz frequencies", Phys. Rev. A 111: 063509 (2025)

[4]S. Gu, C. Wang, Z. Gao, L. Gao, F. Gao, S. Wang, and Y. Xu, "Discrete Ultra-Broadband Perfect Anomalous Reflection in Depth Gradient Metasurfaces", Chin. Phys. Lett. 42: 090401 (2025)

[5]K. Wu, C. Zhang, K. Zhang, S. Wang et al. "Plasmonic Quasi-Bound States in Continuum Facilitated Bulk Photovoltaic Effect for Spectrally Selective and Polarization-Sensitive Bipolar Photodetection", ACS Photonics 12: 4388 (2025)

[6]Y. Luo, T. Yu, K. Zhang, P. Sun, K. Wu, S. Wu, J. Yang, S. Wang et al. "All-Silicon Dual-Wavelength Hot-Electron Photodetector with Quasi-Omnidirectional Schottky Interface for Ultralow-Noise Equivalent Power Encrypted Demultiplexing Telecommunication", ACS Photonics 12: 5501 (2025)

[7]Y. Zhai, C. Xu, Z. Zhang, P. Li, S. Murai, J. Gomez Rivas, X. Li, and S. Wang, "Efficient Redirection of Trapped Broad-Band Fluorescence from Substrates into Free Space Using c-Si Metasurfaces", Nano Lett. 24: 11311 (2024).

Research Spotlight: a c-Si metasurface on quartz diffractively redirects substrate-trapped broadband (RGB) fluorescence into free space, boosting photoluminescence by 2.5× and improving emission uniformity.

[8]王绍军，张郑合，侯紫玥，翟一恒，徐超捷，李孝峰，“超构表面调控可见光发射及其应用（特邀）”，激光与光电子学进展 61:0323001（2024).

S.Wang, Z. Zhang, Z. Hou, Y. Zhai, C. Xu, and X. Li, "Metasurfaces for Manipulating and Controlling Visible-Light Emission and Its Applications (Invited)", Laser Optoelectron. P. 61: 0323001 (2024).

[9]T. Ma, H. Wang, Z. Wu, Y. Zhao, C. Chen, X. Yin, L. Hu, F. Yao, Q. Lin, S. Wang, D. Zhao, X. Li, and C. Wang, "Hole Transport Layer-Free Low-Bandgap Perovskite Solar Cells for Efficient All-Perovskite Tandems", Adv. Mater. 36: 2308240(2024).

[10]Z. Chem, F. Shen, Z. Zhang, K. Wu, Y. Jing, M. Long, S. Wang, and J. Xu, "Synergistic Effect of Chiral Metasurface and Hot Carrier Injection Enabling Manipulation of Valley Polarization of WSe2 at Room Temperature",  Adv. Phys. Res. 3: 2300062 (2024). 

[11]Y. Zhang, Z. Zhang, C. Xu, W. Lu, Z. Chen, C. Wang, F. Xiao, S. Wang, and X. Li, “Precisely constructing hybrid nanogap arrays via wet-transfer of dielectric metasurfaces onto a plasmonic mirror”, Opt. Express 31, 34280 (2023)

Research Spotlight: we demonstrate a scalable wet-transfer fabrication method for hybrid Mie–plasmonic metasurfaces that immobilizes monocrystalline Si nanoantenna arrays on ultrasmooth gold, enabling oxide- and nanogap-mediated hybrid modes (including BICs) with strong field enhancement for active metasurface applications (e.g., MEMS and LiDAR).

[12]Z. Zhang, C. Xu, C. Liu, M. Lang, Y. Zhang, M. Li, W. Lu, Z. Chen, C. Wang, S. Wang, and X. Li, "Dual Control of Enhanced Quasi-Bound States in the Continuum Emission from Resonant c-Si Metasurfaces", Nano Lett. 16, 7584 (2023).

Research Spotlight: we present a lattice- and multipolar-engineering strategy that boosts out-coupling and directional emission from quasi-BICs in monocrystalline silicon metasurfaces, turning otherwise weakly emitting high-Q resonances into brighter, device-relevant light sources for compact LEDs, lasers, and on-chip nanophotonics.

[13]C. Zhang, B. Huang, H. Li, H. Chen, T. Yu, B. Zhang, S. Wang, C Liu, Y Luo, SA Maier, and X Li，“Plasmonic Nanoneedle Arrays with Enhanced Hot Electron Photodetection for Near‐IR Imaging”，Adv. Funct. Mater. 33, 2304368 (2023)

[14]Z. Zhang, P. Liu, W. Lu, P. Bai, B. Zhang, Z. Chen, S. A. Maier, J. Gómez Rivas, S. Wang, and X. Li, “High-Q Collective Mie Resonances in Monocrystalline Silicon Nanoantenna Arrays for the Visible Light”, Fundam. Res.3，822 (2023). 

Research Spotlight: the water-floating (float-off) transfer is the key advance in this work. It firstly enables low-loss c-Si metasurfaces fabricated on SOI to be reliably transferred and integrated a flexible metasurface membrane onto a wide range of functional substrates (e.g., quartz, glass, PDMS, lithium niobate, and device stacks), greatly expanding integration options while preserving optical performance.

[15]P. Liu, Z. Zhang, M. Lang, W. Lu, P. Bai, Z. Chen, S. Wang, and X. Li, “Manipulating the Directional Emission of Monolayer Semiconductors by Dielectric Nanoantenna Arrays”, J. Opt.24, 24005 (2022).

[16]F. Shen, Z. Zhang, Y. Zhou, J. Ma, K. Chen, H. Chen, S. Wang, J. Xu, and Z. Chen, "Transition metal dichalcogenide metaphotonic and self-coupled polaritonic platform grown by chemical vapor deposition",  Nat. Commun. 13, 5597 (2022).

[17]R. H. Godiksen, S. Wang, TV Raziman, J. Gómez Rivas, and A. G. Curto, "Impact of indirect transitions on valley polarization in WS2 and WSe2", Nanoscale 14, 17761(2022).

[18]T. V. Raziman, C. Peter Visser, S. Wang, J. Gómez Rivas, and A. G. Curto,“Exciton diffusion and annihilation in nanophotonic Purcell landscapes”, Adv. Opt. Mater. 10, 202200103 (2022).

[19]C. Bian, B. Zhang, Z. Zhang, H. Chen, D. Zhang, S. Wang, J. Ye, L. He, J. Jie, and X. Zhang, “Wafer-Scale Fabrication of Silicon Nanocones via Controlling Catalyst Evolution in All-Wet Metal-Assisted Chemical Etching”, ACS Omega 7, 2234 (2022).

[20]A. Berghuis, T. V. Raziman, A. Halpin, S. Wang, A. G. Curto, and J. Gómez Rivas, “Effective Negative Diffusion of Singlet Excitons in Organic Semiconductors”, J. Phys. Chem. Lett.12, 1360 (2021).

[21]S. Wang, T. V. Raziman, S. Murai, G. W. Castellanos, P. Bai, A. Matthijs Berghuis, R. H. Godiksen, A. G. Curto, and J. Gómez Rivas, "Collective Mie exciton-polaritons in an atomically thin semiconductor", J. Phys. Chem. C 124, 19196 (2020).

[22]R. H. Godiksen, S. Wang, T. V. Raziman, M. H. D. Guimaraes, J. Gómez Rivas, and A. G. Curto, Correlated Fluorescence Fluctuations in a Two-Dimensional Semiconductor, Nano Lett. 20, 4829 (2020).

诚挚地欢迎直博生、考博生、保研生、考研生、大一/二学生加入我们：

苏大META小分队

 2026年5月30日毕业合影

2025年6月毕业合影

2024年6月毕业合影

学术型人才去向：

哈工大-苏大联合培养、浙大直博

公司就业去向：

上海雷鸟科技、杭州玉之泉精密仪器、华宏科技、京东方、第三代半导体研究院、北京豪威、矩阵光电等

致敬母校UDS/Unistra：