纳米光子学-智能光子学创新中心

近场光学

近场光学是研究光与物质在亚波长尺度上相互作用规律，并利用局域电磁场突破传统光学衍射极限实现高分辨探测、成像与调控的重要研究方向。它在纳米尺度上直接获取材料的局域光学响应、载流子分布、振动态信息以及界面电磁行为，一方面发展覆盖可见光、红外到太赫兹波段的高空间分辨近场成像与光谱平台，另一方面面向低维材料、强关联体系和人工微纳结构，研究微纳光场传播、局域场增强、超快动力学及缺陷表征机制。这种近场研究方式兼具高空间分辨率、多谱段兼容性和多物理场耦合能力，能够为新型光电子器件、量子材料表征、光场调控以及高端半导体检测提供关键技术支撑，是连接基础光学前沿与先进光子器件应用的重要方向之一。

4D114

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光学超构表面

光学超构表面是一种新型的平面光学元件，其由在二维平面上周期排布的亚波长人工结构阵列构成，能够对入射光场的振幅、相位、偏振以及轨道角动量等多维度光学参量进行精确独立的调控。与传统折射光学元件依赖于光波在介质中传播时逐渐积累的相位变化不同，超构表面通过结构单元对局部光场引入相位、振幅等参量的突变，使得在波长尺度完成光波的调控，从而极大地压缩了光学系统的体积与重量，提升了设计的灵活性与紧凑性。作为平面光学元件，超构表面具有鲁棒性好、集成度高、与CMOS工艺兼容等优势，能够实现低成本、大面积、高一致性的大规模制备，推动了光学器件从空间堆叠向平面化、芯片化方向发展。超构表面已成功应用于高分辨率成像、全光图像处理、波前整形和全息显示等场景。在片上系统中，超构表面也能够用于AR近眼显示、波导模式耦合与转换以及光学信号路由等领域。

1680E9

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低维量子材料

低维半导体材料具有强量子限域效应，使得其在亚纳米尺度内依然能保持优异的光电性能。本课题组聚焦低维过渡金属硫化物（TMDs）、低维钙钛矿材料及其异质集成，通过稳态及瞬态光谱技术（如荧光光谱、时间分辨光谱）精准解析光生载流子产生、复合的微观过程，并研制具有偏振敏感、波长分辨功能的多维光电探测器。该研究有望突破传统半导体材料量子效应的限制，实现高性能、多功能的亚纳米集成光子、光电子器件，为“后摩尔”时代提供关键半导体材料平台。

参考文献

研究方向

[1] Weiliang Ma, Guangwei Hu, Debo Hu, Runkun Chen, Tian Sun, Xinliang Zhang, Qing Dai, Ying Zeng, Andrea Alù, Cheng-Wei Qiu, and Peining Li. Ghost hyperbolic surface polaritons in bulk anisotropic crystals. <em><strong> Nature </strong></em>, 596(7872): 362–366 (2021).

[3] Tian Sun, Runkun Chen, Weiliang Ma, Han Wang, Qizhi Yan, Junhua Luo, Sangen Zhao, Xinliang Zhang, and Peining Li. Van der Waals quaternary oxides for tunable low-loss anisotropic polaritonics. <em><strong> Nature Nanotechnology </strong></em> , 19(6): 758–765 (2024)

[4] Yingjie Wu, Jiahua Duan, Weiliang Ma, Qingdong Ou, Peining Li, Pablo Alonso-González, Joshua D. Caldwell, and Qiaoliang Bao. Manipulating polaritons at the extreme scale in van der Waals materials. <em><strong> Nature Reviews Physics </strong></em> , 4(9): 578–594 (2022)

[8] Xin Zhang, Qizhi Yan, Weiliang Ma, Tianning Zhang, Xiaosheng Yang, Xinliang Zhang, and Peining Li. Ultrafast anisotropic dynamics of hyperbolic nanolight pulse propagation. <em><strong> Science Advances </strong></em> , 9(34): eadi4407 (2023)

[10] Caixing Hu, Tian Sun, Ying Zeng, Weiliang Ma, Zhigao Dai, Xiaosheng Yang, Xinliang Zhang, and Peining Li. Source-configured symmetry-broken hyperbolic polaritons. <em><strong> eLight </strong></em> , 3(1): 14 (2023).

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[8] Z. Liu, C. Zhang, W. Zhu, Z. Huang, H. J. Lezec, A. Agrawal, and L. J. Guo, “Compact Stereo Waveguide Display Based on a Unidirectional Polarization-Multiplexed Metagrating In-Coupler”, <em><strong> ACS Photonics </strong></em> 8, 1112, 2021

[9] Z. Liu, H. Gao, T. Ma, V. Ray, N. Liu, X. Zhang, L. J. Guo, C. Zhang, “Broadband Spin and Angle Co-multiplexed Waveguide-based Metasurface for Six-channel Crosstalk-free Holographic Projection”, <em><strong> eLight </strong></em> 4, 7, 2024

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[1] Haizhen Wang, Fupeng Zhang, Ziyao Gao, Anaoxue Huang, Zeyi Liu, Xingsheng Wang, Xinliang Zhang, Dehui Li. Enhanced Spectral Modulation for a High-Performance Miniaturized Spectrometer. <em><strong> Nano Letters </strong></em> 25, 15964-15969 (2025)

[2] Yue Hu, Jingwen Chen, Ruoxuan Xing, Dehui Li, Xinglin Wen. Robust Emission of Dark Trions in WS2/WSe2 Heterostructure. <em><strong> Nano Letters </strong></em> 25, 14518-14525 (2025)

[3] Changming Yang, Zeyi Liu, Hongjun Cai, Dehui Li, Yu Yu, Xinliang Zhang. High-Speed and High-Responsivity Vertical van der Waals Heterostructure Waveguide Photodetector Operating in Telecom Band. <em><strong> ACS Nano </strong></em> 19, 8661-8666 (2025)

[4] Zeyi Liu, Yingying Chen, Junze Li, Wendian Yao, Ting Luo, Dehui Li. Probing Local Structural Phase Transition at the Surface of (BA)2PbI4 via Interlayer Exciton Emission. <em><strong> Advanced Functional Materials. </strong></em> 34, 2312074 (2024)

[5] Tong Ye, Yongzhuo Li, Junze Li, Hongzhi Shen, Junwen Ren, Cun-Zheng Ning, Dehui Li .Nonvolatile electrical switching of optical and valleytronic properties of interlayer excitons. <em><strong> Light: Science & Applications </strong></em> 11:23 (2022)

[6] Chen Fang, Junze Li, Boxuan Zhou, Dehui Li. Self-powered filterless on-chip full-stokes polarimeter. <em><strong> Nano Letters </strong></em> 21, 6156-6162 (2021)

[7] Yingying Chen, Jiaqi Ma, Zeyi Liu, Junze Li, Xiangfeng Duan, Dehui Li. Manipulation of Valley Pseudospin by Selective Spin Injection in Chiral Two-Dimensional Perovskite/Monolayer Transition Metal Dichalcogenide Heterostructures. <em><strong> ACS Nano </strong></em> 14, 15154–15160 (2020)

[8] Yingying Chen, Zeyi Liu, Junze Li, Xue Cheng, Jiaqi Ma, Haizhen Wang, Dehui Li. Robust interlayer coupling in two-dimensional perovskite/monolayer transition metal dichalcogenide heterostructures. <em><strong> ACS Nano </strong></em> 14, 10258-10264 (2020)

[9] Junze Li, Jun Wang, Jiaqi Ma, Hongzhi Shen, Lu Li, Xiangfeng Duan, Dehui Li. Self-trapped state enabled filterless narrowband photodetections in 2D layered perovskite single crystals. <em><strong> Nature Communications </strong></em> 10:806 (2019)

[10] Jiaqi Ma, Chen Fang, Chao Chen, Long Jin, Jiaqi Wang, Shuai Wang, Jiang Tang, Dehui Li. Chiral 2D perovskites with a high degree of circularly polarized photoluminescence. <em><strong> ACS Nano </strong></em> 13, 3659-3665 (2019)

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