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湖南省重点实验室 信息光子学与空间光通信


实验室概况


信息光子学与空间光通信湖南省重点实验室是在新葡的京集团350vip8888先进光学研究所的基础上,于2018年申请,2019年12月通过湖南省科技厅审查,批准立项成立。实验室将在省科技厅和新葡的京集团350vip8888的宏观指导和政策支持下,按照省重点实验室建设管理办法要求,依托湖南省双一流学科、博士学位授权立项建设学科“信息与通信工程学科”,立足学术前沿并瞄准国家和我省对信息光子学与空间光通信的相关领域的重大需求,以“出成果、出人才、出效益”为目标,针对光与复杂介质相互作用中的超高速大容量空间光传输和超分辨高灵敏光信息获取的基础理论、材料器件和系统应用等核心问题,围绕信息光子学理论、新型光电材料与器件、空间光通信与光电信息处理三个方向开展科学研究与技术开发,力争将本实验室建设成省内一流、国内先进的本领域的科技创新、成果转化、人才培养和学术交流基地。


研究方向和主要研究内容


1)信息光子学理论:研究光子的自旋-轨道相互作用,探索形成量子测量探测技术的理论,为传感器和测量科学提供新的机制或模式;研究复杂介质与传播光场的相互作用机理及介质中的光传输特性,探索建立描述复杂介质物理特性的理论模型,为空间光通信、分子医学成像等提供全新的理论指导;研究光在生物组织和细胞中的散射传输,建立生物组织多光谱光学特性测量及细胞偏振衍射测量模型,为新型光谱仪和双偏振衍射流式细胞仪应用提供理论支持;研究半导体纳米材料等光电材料的电学和光学性能以及其独特的光束传输特性,为光电材料器件的设计、应用和制备提供新的理论依据。

2)新型光电材料与器件:研究掺杂半导体超材料的光学特性及其调控机理,为设计光束高效调控与检测的光学元器件提供新的技术方案;研究光电调制、探测及场效应晶体管器件的设计与优化,为光信息的加载与获取提供高性能器件;研究新波长激光、新型正交偏振双波长激光及其高效和频光,为空间光通信与光电信息处理的研究提供高性能激光光源;研究近中远红外波段的二阶非线性光学测试方法,为评估新型光电功能材料的综合性能提供设备支持。

3)空间光通信与光电信息处理:研究复杂介质中传播光场参量的自适应调控原理与技术,为超高速空间光通信提供新的技术支撑;研究光电信息加密与传输中的非线性电路系统构建、分析、同步等基础性问题,及随机序列复杂性、图像数据加密及传输安全性与有效性等关键技术问题,为保密空间光通信提供新的视角;开展光与生物组织、细胞的相互作用,新型高精度多光谱测量技术及细胞精细分型研究,探索其在生物医学、食品药品检测、临床诊断等方面的应用研究。


实验室学术委员会


文双春 张春熹  董建绩  秦石乔  钟建新  王兵  唐东升  刘靖


信息光子学与光信息处理团队成员


胡新华  

元秀华

张春熹

田芃  

王文进

文于华

闵力

金佳鸿

徐白


科研条件


学校先后投入500余万元,购置了双偏振衍射成像流式细胞仪、高速FPGA开发平台、荧光倒置显微镜、光纤光谱仪、液晶可调滤波器、CCD相机、红外相机、数字示波器、计算集群(含GPU计算工作站5台,CPU计算工作站2台和存储管理节点1台)、波前畸变矫正仪、空间光调制器等设备。


科研成果


论文

[1]  Tian P, Qin Y, Zhao L, Mutisya SM, Jin J, Lu JQ, Hu XH: Multiparameter Spectrophotometry Platform for Turbid Sample Measurement by Robust Solutions of Radiative Transfer Problems. IEEE Transactions on Instrumentation and Measurement 2020:3032184.

[2]  Tian P, Mutisya SM, Jin J, Zheng S, Lu JQ, Hu X-H: Spectral determination of μa, μs and g from single and multiple scattering signals with one optically thick sample. Journal of Quantitative Spectroscopy and Radiative Transfer 2020, 245:106868.

[3]  Liu J, Xu Y, Wang W, Wen Y, Hong H, Lu JQ, Tian P*, Hu X-H*: Machine learning of diffraction image patterns for accurate classification of cells modeled with different nuclear sizes. Journal of Biophotonics 2020, e20200036.1-13

[4]  Zhou Z, Zhou X, Yuan X*, Tian P*: Research on characteristics of Bessel–Gaussian Schell-model beam in weak turbulence. Optics Communications 2020, 474:126074.

[5]  田芃, 郑帅, 梁振木, 刘靖: LED可见光语音传输及温度监测系统.电子测量技术 2020, 43(17):126-129.

[6]  Zhou X, Zhou Z, Tian P*, Yuan X: Numerical research on partially coherent flat-topped beam propagation through atmospheric turbulence along a slant path. Applied Optics 2019, 58(34):9443-9454.

[7]  Tian P, Mutisya SM, Jin J, Lu JQ, Hu X-H. Spectral determination of μa, μs and g of one thick turbid sample from three scattered light signals, SPIE(European Conferences on Biomedical Optics), 2019(11074), 110742G

[8]  Tian P, Chen C, Jin J, Hong H, Lu JQ, Hu X-H. Quantitative characterization of turbidity by radiative transfer based reflectance imaging. Biomedical Optics Express 2018, 9(5):2081-2094.

[9]  Peng T, Xun C, Jiahong J, Jun Q L, Xiaohui L, Xin-hua H. A stochastic model for quantifying surface roughness and effect on light reflection by diffuse reflectance standards. Optical Engineering 2018, 57(9):094104.

[10]  Jiang Zhao, Bo Li, Heng Zhao, Wenjin Wang, et al. Nonparaxial circular grating diffraction properties of radially polarized beams. Optics Communications. 2014, 323: 61-67. SCI

[11]  Jiang Zhao, Bo Li, Heng Zhao, Wenjin Wang, et al. Generation of azimuthally polarized beams in FAF CO2 laser with hybrid circular subwavelength grating mirror. Applied Optics, 2014, 53(17): 3706-3711. SCI

[12]  Wenjin Wang, Bo Li, Heng Zhao, Yi Hu, Youqing Wang, Optimum structural design of a heat exchanger for gas-circulation systems. Energy Conversion and Management, Volume 94, April 2015, Pages 190-197. SCI

[13]  Wenjin Wang, Yang Bao, Youqing Wang, Numerical investigation of a finned-tube heat exchanger with novel longitudinal vortex generators. Applied Thermal Engineering, Volume 86, 5 July 2015, Pages 27-34. SCI

[14]  Wenjin Wang, xin-hua Hu. Resolving power of diffraction imaging with an objective: a numerical study. Optics Express, Volume 259, May 2017, Pages 28-33. SCI

[15]  Wenjin Wang, Yuhua Wen, xin-hua Hu, et al. Rapid classification of micron-sized particles of sphere, cylinders and ellipsoids by diffraction image parameters combined with scattered light intensity. Journal of Quantitative Spectroscopy and Radiative Transfer, Volume 224, February 2019, Pages 453-459.SCI

[16]  S. Wang, J. Liu, J.Q. Lu, Wenjin Wang, X.H. Hu, et al. Development and evaluation of realistic optical cell models for rapid and label-free cell assay by diffraction imaging, Journal of Biophotonics, Volume 12, February 2019e201800287. SCI

[17]  J. Liu, Y. Xu, Wenjin Wang, et al. Machine learning of diffraction image patterns for accurate classification of cells modeled with different nuclear sizes, Journal of Biophotonics, Volume 13, 2020, e202000036. SCI

[18]  L. Min*, L. Huang, R. Sun, Z. Li. Incidence ways of electromagnetic wave and their influences on the absorption and resonant wavelength of split-ring resonators, Plasmonics, 10 (2015) 183-189. SCI

[19]  L. Min*, L. Huang. All-semiconductor optical microcircuit board, Conference on Lasers and Electro-Optics (CLEO) ,2 (2015) 1-2. EI

[20]  L. Min*, L. Huang. Perspective on resonances of metamaterials, Optics Express, 23 (2015) 19022-19033. SCI

[21]  L. Min*, L. Huang, R. Sun, M. Xi. Dual Metamaterial With Large Birefringence, IEEE Photonics Journal, 7 (2015) 1-1. SCI

[22]  L. Min*, L. Huang. All-semiconductor metamaterial-based optical circuit board at the microscale, Journal of Applied Physics, 118 (2015) 013104. SCI

[23]  童耀南闵力,罗朝明,周峰等. 层状人工光学材料传输特性分析软件V1.0. 软件著作权. 登记号:2019SR0160413, No.03621443.

[24]  闵力,童耀南,罗朝明,周峰等. 光学材料有效电磁常数分析软件V1.0. 软件著作权. 登记号:2019SR0160356No.03621430.

[25]  Li Min*, Wenjin Wang, Yuhua Wen, et al. Electromagnetic resonance strength in metamaterials. Journal of Applied Physics, 2019, 126(2):023103-(1-6). (SCI)

[26]  Li Min*, Wenjin Wang, Lirong Huang, et al. Direct-tuning methods for semiconductor metamaterials, 2019, 9(1):1-6. SCI

[27]  Yuhua Wen, Zhiyuan He, Jialin Li, Ruihong Luo, Peng Xiang, Qingyu Deng,Guangning Xu, Zhen Shen, Zhisheng Wu, Baijun Zhang, Hao Jiang, Gang Wang, and Yang Liu. Enhancement-mode AlGaN/GaN heterostructure field effect transistors fabricated by selective area growth technique. Appl. Phys. Lett. 98, 072108:1-3, 201

[28]  2. Yuhua Wen, Zhan Chen, Jianfen Lu, Elizabeth Ables, Jean-Luc Scemama, Li V. Yang, Jun Q. Lu, Xin-Hua Hu*.Quantitative analysis and comparison of 3D morphology between viable and apoptotic MCF-7 breast cancer cells and characterization of nuclear fragmentation. PLoS  ONE, 2017, 12(9): e0184726

[29]  Jin J, Lu J Q, Wen Y, et al. Deep learning of diffraction image patterns for accurate classification of five cell types[J]. Journal of biophotonics, 2020, 13(3): e201900242. (SCI).

[30]  Bai XuYongda Li. Numerical simulations of THz emission from the laser wakefields through linear mode conversion, Optics & Laser Technology, 2012, (SCI).

[31]  Bai XuYongda Li. Simulation of THz emission from laser interaction with plasmas, Optik, 2012, (SCI).

[32]  Bai XuYongda Li. Numerical simulations of THz emission from the laser interaction with magnetized plasmas, Optik, 2012, (SCI).



专利

[1]  田芃,黄黎蓉,石中卫,黄德修,元秀华,阎利杰. 量子点分子发光器件. 发明专利. CN 102097564 B. 2013.3.24

[2]  田芃, 李敏聪, 周峰. 一种带示温功能的电烙铁. 实用新型专利. CN 205519982 U. 2016.8.31.

[3]  田芃,胡新华,金佳鸿,卢军青. 浑浊介质多参数光谱测量方法及测量系统. 国家发明专利. CN201811554510.8

[4]  闵力*;李宏民;魏勇等. 一种偏振不敏感太赫兹掺杂半导体超材料透镜. 国家发明专利(专利号:ZL201910269060.6,授权公告号:CN 110018531 B