你在这里

js65金沙线路总站 » 人员 » 梁浩文

梁浩文

职       称:教授 博士生导师

毕业院校:中山大学

电子邮箱:lianghw26@mail.sysu.edu.cn

主要经历: 

工作经历:

2026/01 - 至今,中山大学,js65金沙线路总站,教授

2019/11 - 2026/01,中山大学,js65金沙线路总站,副教授

2016/12 - 2019/11,中山大学,js65金沙线路总站,副研究员

教育经历:

2011/9 - 2016/6,中山大学,光学工程,博士

2014/10 - 2016/9,美国中佛罗里达大学,光学院(CREOL),访问学者

2007/9 - 2011/6,中山大学,物理学,学士

学科方向: 

主要从事微纳光场调控与成像显示应用相关研究,研究方向包括:

(1)微纳光场色散调控:消色差/ 色散工程原理创新、器件设计、成像与显示应用;

(2)微纳光场相位调控:局域光场压缩原理创新、器件设计、超分辨光场应用;

(3)微纳光场多维调控:多维光场调控原理创新、器件设计、多功能成像应用。

 

研究内容应用于成像与显示产品、医工交叉技术、集成电路光刻与检测技术上。欢迎业界同仁联系交流。

计划招收光学方向博士、硕士研究生,欢迎联系。

 

承担课题: 

主持、参与多项国家级及省部级项目,包括:

  1. 广东省自然科学基金面上项目,2025 - 2027,主持
  2. 广东省基础与应用基础研究重大项目,2021 - 2025,项目骨干
  3. 广州市基础与应用基础研究项目,2021 - 2023,主持
  4. 国家自然科学基金委面上项目,2021 - 2024,主持
  5. 广东省重点领域研发计划(课题),2020 - 2022,主持
  6. 国家科技创新项目,2020年度,主持
  7. 国家重点研发计划(课题),2020 - 2023,主持
  8. 广东省自然科学基金面上项目,2019 - 2022,主持
  9. 国家科技创新项目,2019年度,主持
  10. 国家自然科学基金委青年项目,2018 - 2020,主持
荣誉获奖: 
  1. 2022年 "广东特支计划"科技创新青年拔尖人才
  2. 获科技委奖项1项。
  3. 超大数值孔径超构透镜成果入选美国光学学会2018年度重要成果(OPTICS 2018)
主要兼职: 
  1. 中国光学工程学会计算成像专家委员会青年委员 
  2. 中国光学工程学会光电融合专业委员会成像与显示专业组委员
  3. 中国光学工程学会微纳专业委员会秘书
  4. 国际信息显示学会北京分会技术委员会委员
  5. 国家科技重点项目专家
  6. 南方海洋科学与工程广东省实验室(珠海)固定成员
  7. 中国图象图形学学会三维成像与显示专业委员会委员
代表论著: 

发表论文:

成像应用:

  1. Z. Wang, J. Wang, H. Liang*, J. Li, "Trans-reflective RGB achromatic metalens for wide field-of-view and high readability augmented reality imaging," Chin. Opt. Lett., 24(1), 013603 (2026).
  2. H. Liang*, W. Ye, M. Gao, L. Chen, Y. Liu, J. Wang, J. Li, J. Yuan, X. -H. Wang, "An optical meta-image-processor for enhanced imaging through strongly scattering media," Nature Commun., 16, 9732 (2025).
  3. P. Zhang, L. Yan, H. Liang*, J. Zhang*, J. Li*, X. -H. Wang, "RGB Achromatic Metalens for Neural Network-Enhanced High Resolution Digital Imaging," Laser & Photon. Rev., e00460 (2025). (Front Cover)
  4. J. Lin1, J. Chen1, J. Zhang, H. Liang*, J. Li*, and X. -H. Wang*, "High-performance achromatic flat lens by multiplexing meta-atoms on a stepwise phase dispersion compensation layer," Light: Sci. & Appl., 14, 110 (2025). (Front Cover)
  5. D. Yang, J. Zhang, P. Zhang, H. Liang*, J. Ma*, J. Li*, and X. -H. Wang, "Optical trapping and manipulating with a transmissive and polarization-insensitive metalens," Nanophotonics, 13(15), 2781-2789 (2024).
  6. J. Zhang, Q. Sun, Z. Wang, G. Zhang, Y. Liu, J. Liu, E. R. Martins, T. F. Krauss, H. Liang*, J. Li*, and X. -H. Wang, "A Fully Metaoptical Zoom Lens with a Wide Range," Nano Lett. 24 (16), 4893–4899 (2024). (Front Cover)
  7. Y. Li, X. Huang, S. Liu*, H. Liang*, Y. Ling, and Y. Su*, "Metasurfaces for near-eye display applications," Opto-Electronic Science, 2, 230025 (2023). 
  8. Y. Shui, T. Wang, J. Zhou, X. Luo, Y. Liu*, and H. Liang*, "Scattered light imaging beyond the memory effect using the dynamic properties of thick turbid media," Adv. Photon. Nexus 2(2), 026010 (2023).
  9. L. Luo, Z. Wang, J. Li, and H. Liang*, "Wide-Field-of-View Trans-Reflective RGB-Achromatic Metalens for Augmented Reality," Photonics, 10, 590 (2023). (光学超构透镜与增强现实显示交叉)
  10. R. Zhong, X. Xu, Y. Zhou, H. Liang, and J. Li*, "High-Efficiency Integrated Color Routers by Simple Identical Nanostructures for Visible and Near-Infrared Wavelengths," Photonics, 10, 536 (2023).
  11. Y. Li1, S. Chen1, H. Liang*, X. Ren, L. Luo, Y. Ling, S. Liu, Y. Su*, and S. -T. Wu*, "Ultracompact multifunctional metalens visor for augmented reality displays," PhotoniX, 3:29 (2022). (光学超构透镜与增强现实显示交叉)
  12. J. Zhang, H. Liang*, Y. Long, Y. Zhou, Q. Sun, Q. Wu, X. Fu*, E. R. Martins, T. F. Thomas, J. Li*, and X. -H. Wang, "Metalenses with Polarization-Insensitive Adaptive Nano-Antennas," Laser & Photon. Rev., 16(9), 2200268 (2022). (Front Cover)
  13. G. Guang1, A. Zhang1, X. Xie, Y. Meng, W. Zhang, J. Zhou*, and H. Liang*, "Far-Field and Non-Intrusive Optical Mapping of Nanoscale Structures," Nanomaterials, 12, 2274 (2022).
  14. W. Feng, J. Zhang, Q. Wu, A. Martins, Q. Sun, Z. Liu, Y. Long, E. R. Martins, J. Li*, and H. Liang*, "RGB Achromatic Metalens Doublet for Digital Imaging," Nano Lett., 22, 3969 - 3975 (2022).
  15. Y. Long, J. Zhang, Z. Liu, W. Feng, S. Guo, Q. Sun, Q. Wu, X. Yu, J. Zhou, E. R. Martins, H. Liang*, and J. Li*, "Metalens-based stereoscopic microscope," Photon. Res. 10(6), 1501 - 1508 (2022).
  16. A. Martins*, K. Li, G. S. Arruda, D. Conteduca, H. Liang, J. Li, B. -H. V. Borges, T. F. Thomas, and E. R. Martins*, "Correction of Aberrations via Polarization in Single Layer Metalenses," Adv. Opt. Mater., 10(9), 2102555, (2022).
  17. T. Ye, D. Wu, Q. Wu, X. W. Sun, H. Liang*, K. Wang*, and M. Hong*, "Realization of inversely designed metagrating for highly efficient large angle beam deflection," Opt. Express 30(5), 7566 - 7579 (2022).
  18. Z. Liu, W. Feng, Y. Long, S. Guo, H. Liang, Z. Qiu, X. Fu*, and J. Li, "A Metasurface Beam Combiner Based on the Control of Angular Response," Photonics 8, 489 (2021).
  19. X. Fu, H. Liang*, and J. Li, "Metalenses: from design principles to functional applications," Front. Optoelectron. 48 (2021).
  20. Y. Huang1, Y. Liu1, H. Liu, Y. Shui, G. Zhao, J. Chu, G. Situ, Z. Li, J. Zhou, and H. Liang*, "Multi-View Optical Image Fusion and Reconstruction for Defogging without a Prior In-Plane," Photonics, 8, 454 (2021). 
  21. Q. Sun, H. Liang*, J. Zhang, W. Feng, E. R. Martins, T. F. Krauss, and J. Li*, "Highly Efficient Air-Mode Silicon Metasurfaces for Visible Light Operation Embedded in a Protective Silica Layer,"  Adv. Opt. Mater. 9(11), 2002209 (2021). (Inside Front Cover)
  22. J. Lin, Q. Sun, W. Feng, S. Guo, Z. Liu, H. Liang*, and J. Li, "Enhancing the Light Extraction Efficiency in Micro-Organic Light-Emitting Diodes with Metalens," Adv. Photon. Res. 2(6), 2000145 (2021).(Front Cover)
  23. A. Martins, K. Li, J. Li, H. Liang, D. Conteduca, B. -H. V. Borges, T. F. Thomas, and E. R. Martins*, "On Metalenses with Arbitrarily Wide Field of View", ACS Photonics 7, 2073 - 2079 (2020) .
  24. H. Liang1, A. Martins1, B. -H. V. Borges, J. Zhou, E. R. Martins, J. Li *, and T. F. Krauss, "High performance metalenses: numerical aperture, aberrations, chromaticity, and trade-offs", Optica 6(12), 1461 – 1470 (2019). (Invited Review, Front Cover)
  25. H. Li, D. P. Stellinga, Y. Qiu, Q. Sun, B. Chen, H. Liang*, T. F. Krauss, and J. Li, "Ultra-thin transmissive crystalline silicon high-contrast grating metasurfaces", Opt. Express 27(21), 30931 – 30940 (2019).
  26. Y. Qiu, F. Zhao, X. Zhu, J. Li, H. Liang*, J. Wang, and Z. Cai, “Deflecting transmissive light beams with metasurfaces based on crystalline silicon high-contrast grating,” J. Phys. D: Appl. Phys. 52(8), 084001 (2019).
  27. Y. Liu, H. Liang, C. W. Chen, X. Xie, W. Hu, P. Chen, J. Wen, J. Zhou*, T. H. Lin, and I. C. Khoo, “Ultrafast switching of optical singularity eigenstates with compact integrable liquid crystal structures,” Opt. Express 26(22), 28818-28826 (2018).
  28. H. Liang, Q. Lin, X. Xie, Q. Sun, Y. Wang, L. Zhou, L. Liu, X. Yu, J. Zhou, J. Li*, and T. F. Krauss, “Ultrahigh Numerical Aperture Metalens at Visible Wavelengths,” Nano Lett. 18(7), 4460-4466 (2018). (OSA OPTICS 2018).

 

显示应用:

  1. X. Huang, Y. Zhou, H. Liang*, and J. Zhou, "Binocular near-eye augmented reality enabled by full utilization of functional computer generated hologram," Opt. & Lasers Eng., 176, 108115, (2024).
  2. Y. Ding, Q. Yang, Y. Li, Z. Yang, Z. Wang, H. Liang*, and S.-T. Wu*, "Waveguide-based augmented reality displays: perspective and challenges," eLight, 3:24, (2023).
  3. H. Xu, S. Tabata, H. Liang*, L. Wang*, and M. Ishikawa, "Accurate measurement of virtual image distance for near-eye displays based on auto-focusing," Appl. Opt., 61(30), 9093 - 9098 (2022).
  4. M. Cheng, J. Zhong, Y. Wang, J. Li, J. Yuan, J. He, J. Wang, H. Liang*, and J. Zhou, "Quantifying perceptual resolution for autostereoscopic three-dimensional displays," J. Soc. Inf. Disp. DOI: 10.1002/jsid.1179 (2022).
  5. Y. Wang1, J. Zhong1, M. Cheng, J. Li, K. Ma, X. Hu, N. Li, H. Liang*, Z. Zhu, J. Zhou, and J. Yuan*, "A novel clinical dynamic stereopsis assessment based on autostereoscopic display system," Ann. Transl. Med. 10(12), 656 (2022).
  6. H. Zhang, M. Chen, X. Li, K. Li, X. Chen, J. Wang, H. Liang*, J. Zhou*, W. Liang, H. Fan, R. Ding, S. Wang, and D. Deng, "Overcoming lantency with motion prediction in directional autostereoscopic displays," J. SID 28, 252 - 261 (2020).
  7. J. He, Q. Zhang, J. Wang, J. Zhou, and H. Liang*, “Investigation on quantitative uniformity evaluation for directional backlight autostereoscopic displays,” Opt. Express 26(8), 9398-9408 (2018).
  8. H. Liang, Z. Luo, R. Zhu, Y. Dong, J. H. Lee, J. Zhou, and S. T. Wu*, “High efficiency quantum dot and organic LEDs with a back-cavity and a high index substrate,” J. Phys. D: Appl. Phys. 49(14), 145103(2016).
  9. H. Liang, R. Zhu, Y. Dong, S. T. Wu*, J. Li, J. Wang, and J. Zhou, “Enhancing the outcoupling efficiency of quantum dot LEDs with internal nano-scattering pattern,”Opt. Express, 23(10), 12910-12922 (2015).
  10. H. Liang, S. An, J. Wang, Y. Zhou, H. Fan, P. Krebs, and J. Zhou*, “Optimizing Time-Multiplexing Auto-Stereoscopic Displays with a Genetic Algorithm,” J. Disp. Tech., 10 (8), 695 (2014).

 

授权发明专利:

  1. [发明授权] 梁浩文; 叶炜勇; 王雪华; 李俊韬. 一种用于图像增强的超表面器件设计方法及其成像系统 - 202510868367.3; CN 120597354 B, 2026-01-02
  2. [发明授权] 梁浩文; 廖乔林. 结合虚实探针的超高时空分辨率纳米结构测量系统及方法 - 202510749558.8; CN 120274682 B, 2025-09-16
  3. [发明授权] 王雪华; 李俊韬; 梁浩文; 林锦根; 陈进北; 张建超. 一种大数值孔径宽带的消色差平面透镜及其设计方法 - 202410675637.4; CN 118483777 B, 2025-03-18
  4. [发明授权] 李俊韬; 张建超; 梁浩文. 一种高数值孔径超构透镜的设计方法及高数值孔径超构透镜 - 202111666541.4; CN 114397754 B, 2023-06-30
  5. [发明授权] 李俊韬; 梁浩文; 龙勇; 张建超; 周建英. 一种空分超构透镜的设计方法及其立体成像系统 - 202210203651.5; CN 114527569 B, 2023-04-11
  6. [发明授权] 梁浩文; 冯伟彬; 李俊韬; 孙茜; 刘志浩. 一种消色差超构透镜的设计方法及其消色差超构透镜 - 201910086034X; CN 109799611 B, 2021-06-22
  7. [发明授权] 李俊韬;林巧玲;梁浩文;周镇鹏;王饮;周建英;余向阳. 高折射率对比度光栅及其制备方法与应用 - 201810597278.X; CN 108919399 B, 2020-10-16
  8. [发明授权] 梁浩文;李俊韬;林巧玲;孙茜;王嘉辉. 一种超构透镜纳米单元的设计及超构透镜 - 201811133204.X; CN 109283685 B, 2020-10-09