个人简介

谷洪刚（Gu Honggang, Professor），教授，博士生导师，国家级青年人才、中国科协科技智库青年人才。2011年和2016年分别获得华中科技大学机械工程学士和博士学位，2016-2020年在华中科技大学仪器科学与技术博士后流动站工作，2020年6月出站后留校，历任讲师、副教授、教授。 主要从事微纳光学测量技术、仪器与应用方面研究，包括先进光谱椭偏测量、计算光学成像、集成电路测量检测、微纳结构形貌测量、低维材料光学与介电性质研究、半导体材料与器件测量表征、叠层光电器件光学建模仿真与优化设计、超表面/超结构设计与应用等。近年来，主持国家自然科学基金、湖北省重点研发计划、湖北省自然科学基金、广东省自然科学基金青年提升项目等，作为骨干人员参与国家自然科学基金重点项目、国家自然科学基金重大科研仪器研制项目、国家重点研发计划、首批国家重大科学仪器设备开发专项、国家重大科技专项等国家级重大项目。在Nat. Photonics、Light Sci. Appl.、Adv. Opt. Mater.、Nanoscale、Appl. Surf. Sci.、Opt. Lett./Opt. Express等期刊发表SCI论文100余篇，申请发明专项80余件，已获授权50余件（含8件国际专利）。获国际光谱椭偏学会Paul Drude奖（首位获奖华人学者）、中国发明协会发明创业奖∙人物奖、湖北省技术发明一等奖（排4）等，担任国际先进材料学会(IAAM) Fellow、国际光谱椭偏学大会(ICSE)程序委员会委员、中国仪器仪表学会/中国光学学会/中国光学工程学会多个分会委员/理事等。

研究领域

偏振光学测量技术与仪器开发 光电材料光学与介电性质研究 光电器件光学模拟与优化设计

近年来，主要从事先进光谱椭偏测量技术与仪器开发、光电材料光学与介电性质研究、光电器件光学模拟与优化设计等方面的研究工作

近期论文

查看导师新发文章 （温馨提示：请注意重名现象，建议点开原文通过作者单位确认）

近5年代表性论著（*通讯作者，#同等贡献作者） [1]Y Zhou, Z. Guo, H. Gu*, Y. Li, Y. Song, S. Liu, M. Hong, S. Zhao*, and J. Luo*. A solution-processable natural crystal with giant optical anisotropy for efficient manipulation of light polarization. Nat. Photonics, https://doi.org/10.1038/s41566-024-01461-8, 2024. (Accepted) [2]C. Chen, H. Gu*, and S. Liu*. Ultra-simplified diffraction-based computational spectrometer. Light Sci. Appl., 13: 9, 2024. (封面论文) [3]Z. Guo#, H. Gu#,*, Y. Yu, Q. Zhang, Z. Wei*, and S. Liu*. Wavelength-linearly-dependent and polarization-sensitive perfect absorbers based on optically anisotropic germanium selenide (GeSe). Adv. Opt. Mater., 12: 2303138, 2024. [4]L. Liu, W. Li, M. Gong, J. Du, H. Gu*, and S. Liu*. An efficient and robust self-calibration algorithm for planar position errors in ptychographic microscope. IEEE Trans. Instrum. Meas., 73: 4503712, 2024. [5]L. Liu, W. Li, M. Gong, L. Zhong, H. Gu*, and S. Liu*. Resolution-enhanced lensless ptychographic microscope based on maximum-likelihood high-dynamic-range image fusion. IEEE Trans. Instrum. Meas., 73: 4502711, 2024. [6]C. Chen, H. Gu*, and S. Liu*. Noise-robust ptychography using dynamic sigmoid-remolding. Opt. Laser Technol., 172: 110510, 2024. [7]L. Huang, H. Gu*, M. Fang, S. Liu*. Substrate-Tuned Dielectric Screening Effect on Optical Properties of Monolayer MoSe2. Appl. Surf. Sci., 644: 158748 2024. [8]Q. Zhang, H. Gu*, Z. Guo, K. Ding, and S. Liu. Quantitatively exploring giant optical anisotropy of quasi-one-dimensional Ta2NiS5. Nanomaterials, 13: 3098, 2023. [9]P. He, J. Liu, H. Gu*, J. Zhu, H. Jiang, and S. Liu*. EUV mask model based on modified Born series. Opt. Express, 31: 27797-27809, 2023. [10]L. Liu, W. Li, L. Zhong, H. Gu*, and S. Liu*. An adaptive noise-blind-separation algorithm for ptychography. Opt. Lasers Eng., 169: 107748, 2023. [11]C. Chen, J. Liu, J. Zhu, H. Gu*, and S. Liu*. Resolution-enhanced reflection ptychography with axial distance calibration. Opt. Lasers Eng., 169: 107684, 2023. [12]L. Chen, H. Gu*, S. Jiao, and S. Liu. Optical modeling and analysis of pixel OLED by the mixed-level algorithm considering the light leakage effects. Thin Solid Films, 769: 139741, 2023. [13]M. Gong, H. Gu*, C. Chen, J. Chen, W. Li, C. Zhang, and S. Liu. Calibration of residual polarization in light source for broadband rotating polarizer spectroscopic ellipsometer. Thin Solid Films, 769: 139739, 2023 [14]H. Gu, Z. Guo, L. Huang, M. Fang, and S. Liu*. Investigations of optical functions and optical transitions of 2D semiconductors by spectroscopic ellipsometry and DFT. Nanomaterials, 13: 196, 2023. [15]Z. Guo, H. Gu*, Y. Yu, Z. Wei, and S. Liu. Broadband and incident-angle-modulation near-infrared polarizers based on optically anisotropic SnSe. Nanomaterials, 13: 134, 2023. [16]M. Fang, H. Gu*, Z. Guo, J. Liu, and L. Huang, and S. Liu*. Temperature and thickness dependent dielectric functions of MoTe2 thin films investigated by spectroscopic ellipsometry. Appl. Surf. Sci., 605: 154813, 2022. [17]X. Chen*, H. Gu*, J. Liu, C. Chen, and S. Liu*. Advanced Mueller matrix ellipsometry: Instrumentation and emerging applications. Sci. China Tech. Sci., 65: 2007–2030, 2022. [18]Z. Guo, H. Gu*, M. Fang, L. Ye, and S. Liu*. Giant in-plane optical and electronic anisotropy in tellurene: A quantitative exploration. Nanoscale, 14: 12238–12246, 2022. (封面论文) [19]L. Chen, H. Gu*, X. Ke, X. Zhao, K. Ding, S. Jiao, Y. Gu, and S. Liu*. Multi-parameter and multi-objective optimization of stratified OLEDs over wide field-of-view considering thickness tolerance. Opt. Express, 30: 29546–29563, 2022. [20]S. Hou, Z. Guo, T. Xiong, X. Wang, J. Yang, Y. Liu, Z. Niu, S. Liu, B. Liu, S. Zhai*, H. Gu*, and Z. Wei*. Optical and electronic anisotropy of a 2D semiconductor SiP. Nano Res., 15: 8579–8586, 2022 [21]H. Gu, H. Jiang*, X. Chen, C. Zhang, and S. Liu*. Superachromatic polarization modulator for stable and complete polarization measurement over an ultra-wide spectral range. Opt. Express, 30: 15113–15133, 2022. [22]M. Fang#, H. Gu#,*, B. Song, Z. Guo, and S. Liu*. Thickness scaling effects on the complex optical conductivity of few-layer WSe2 investigated by spectroscopic ellipsometry. Adv. Photon. Res., 3: 2100299, 2022. [23]M. Fang#, H. Gu#,*, B. Song, Z. Guo, and S. Liu*. Thickness and layer stacking order effects on complex optical conductivity and exciton strength of few-layer graphene: Implications for optical modulators and photodetectors. ACS Appl. Nano Mater., 5: 1864–1872, 2022. (封面论文) [24]X. Zhao, H. Gu*, L. Chen, and S. Liu*. Optical model and optimization for coherent-Incoherent hybrid organic solar cells with nanostructures. Nanomaterials, 11: 3187, 2021. [25]C. Chen, X. Chen*, C. Wang, S. Sheng, L. Song, H. Gu*, and S. Liu. Imaging Mueller matrix ellipsometry with sub-micron resolution based on back focal plane scanning. Opt. Express, 29: 32712–32727, 2021. [26]Z. Guo#, H. Gu#,*, M. Fang, B. Song, W. Wang*, X. Chen, C. Zhang, H. Jiang, L. Wang, and S. Liu*. Complete dielectric tensor and giant optical anisotropy in quasi-one-dimensional ZrTe5. ACS Mater. Lett., 3: 525–534, 2021. [27]S. Hou, Z. Guo, J. Yang, Y. Liu, W. Shen, C. Hu, S. Liu, H. Gu*, and Z. Wei*. Birefringence and dichroism in quasi-1D transition metal trichalcogenides: Direct experimental investigation. Small, 17: 2100457, 2021. (封面论文) [28]B. Song#, H. Gu#,*, M. Fang, Z. Guo, Y. Ho*, X. Chen, H. Jiang, and S. Liu*. 2D Niobium-doped MoS2: tuning the exciton transitions and potential applications. ACS Appl. Electron. Mater., 3: 2564–2572, 2021. (封面论文) [29]M. Fang#, Z. Wang#, H. Gu*, B. Song, Z. Guo, J. Zhu, X. Chen, C. Zhang, H. Jiang, and S. Liu*. Complex optical conductivity of Bi2Se3 thin film: approaching two-dimensional limit. Appl. Phys. Lett., 118: 191101, 2021 [30]X. Ke, H. Gu*, L. Chen, X. Zhao, J. Tian, Y. Shi, X. Chen, C. Zhang, H. Jiang, and S. Liu*. Multi-objective collaborative optimization strategy for efficiency and chromaticity of stratified OLEDs based on optical simulation method and sensitivity analysis. Opt. Express, 28: 27532–27546, 2020. [31]H. Gu*, S. Zhu, B. Song, M. Fang, Z. Guo, X. Chen*, C. Zhang, H. Jiang, and S. Liu*. An analytical method to determine the complex refractive index of an ultra-thin film by ellipsometry. Appl. Surf. Sci., 507: 145091, 2020.