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教师介绍

沈万福

来源:更新时间:2023-06-05

姓 名 沈万福
职 称 副教授
所在系别 精密仪器工程系
所属课题组 天津大学微纳光学测控实验室
联系电话 18822265292
电子邮件 wfshen@dgquanwei.com
办公地址 第十教学楼414室
主讲课程 《光学仪器设计》,《Python程序设计基础》
导师类型 仪器科学与技术——硕导
电子信息——硕导
通讯地址 天津大学精密仪器与光电子工程学院
邮政编码 300072

个人经历或学术经历

  主要研究方向为微纳测试技术与仪器,包括椭圆偏振光谱、原位光谱测量、表面/界面测量和纳米光子器件等。以第一或通讯作者在ACS Nano, Nanoscale, Advanced Optical Materials, Applied Surface Science, Applied Physics Letters, Optics Letters等发表SCI论文15余篇,其他合作发表高水平SCI论文50余篇,谷歌学术H因子17。现在主持国家自然科学青年基金1项、博士后面上基金1项、科技部重点研发任务2项,作为项目骨干参与科技部重点研发项目2项,国家自然科学基金委重大仪器专项1项,省部级项目5项。获得欧亚太平洋大学联盟奖学金(OeAD)、国家公派留学奖学金(CSC)、天津市优秀博士论文、天津大学优秀博士论文等奖励。

学习经历

  1. 2009.09-2013.06 兰州交通大学机电学院 测控技术与仪器专业 本科;
  2. 2013.09-2019.06 天津大学精仪学院 仪器科学与技术专业 硕博连读;
  3. 2016.09-2017.02 奥地利林茨大学实验物理研究所 博士联合培养;
  4. 2018.01-2019.01 奥地利林茨大学实验物理研究所 博士联合培养;

工作经历

  1. 2019.10-2023.05 天津大学精仪学院 讲师;
  2. 2021.08-2023.05 天津大学仪器科学与技术专业博士后流动站 博士后;
  3. 2023.06-至今 天津大学精仪学院 副教授
研究方向
  1. (1)微纳测试技术及仪器开发
  2. (2)纳米薄膜制备过程中的在线测量(包括化学气相沉积和高真空分子束外延)
  3. (3)晶圆级纳米薄膜可控制备技术
科研项目、成果和专利

科研项目

  1. 1. “极性介电屏蔽调控二维过渡金属硫族化合物光学各向异性的方法研究”,国家自然科学青年基金,2023.01-2025.12,主持
  2. 2. “高性能硅基全光集成纳米偏振器研究”,博士后面上基金,2021.11-2023.05,主持
  3. 3. “复杂产线环境纳米级振动主动控制技术及自稳定云台系统”,国家重点研发计划任务,2020.11-2023.10,主持
  4. 4. “消光式椭偏膜厚测量技术研究”,国家重点研发计划任务,2022.10-2025.11,主持
  5. 5. “光谱色散式膜厚探测器”,国家重点研发计划,2022.11-2025.10,参与
  6. 6. “二维材料的有机分子精准界面调控与器件集成一体化系统”,国家自然科学基金委重大科研仪器研制项目子课题,2020.01-2024.12,参与
  7. 7. 紫外吸收检测器光学设计”,横向课题,2021.12-2022.11,参与
  8. 8. “高空间分辨率超薄膜层结构测量技术与仪器模组开发”,国家重点研发计划子课题,2017.07-2021.06,参与

授权专利

  1. 1. 沈万福,胡春光,马国腾,霍树春,一种自洽验证差分光谱仪及测量方法,中国发明专利,ZL202110615292.X
  2. 2. 沈万福,胡春光,马国腾,霍树春,一种斜入射式光谱型反射差分测量装置及方法,中国发明专利,ZL202110614043.9
  3. 3. 胡春光,马国腾,沈万福,霍树春,一种分源定位真空管式炉装置,中国发明专利,ZL2021105867145
  4. 4. 霍树春,胡春光,王浩,沈万福,姚程源,曲正,武飞宇,胡晓东,胡小唐,用于纳米厚度SiO2厚度的差分反射光谱测量方法,中国发明专利,ZL2019113517057
  5. 5. 胡春光,孙兆阳,沈万福,霍树春,胡晓东,胡小唐,面内各向异性晶体晶轴定向方法及设备,中国发明专利,ZL201810151148.3
  6. 6. 胡春光,孙兆阳,霍树春,沈万福,谢鹏飞,胡晓东,胡小唐,反射差分光学测量装置,中国实用新型专利,ZL2018208170593

计算机软件著作权

  1. 1. 胡春光,王海乐,沈万福,一种自动聚焦成像的差分反射光谱测量系统的操作软件,2022SR1416675;
  2. 2. 胡春光,王浩,霍树春,沈万福,胡小唐,显微式差分反射光谱测量系统的操控软件,2020SR0763241;
  3. 3. 霍树春,王浩,胡春光,沈万福,姚程源,曲正,武飞宇,胡晓东,胡小唐,微区域原位差分反射光谱测量系统的操控软件,2020SR1078141;
  4. 4. 霍树春,王浩,胡春光,沈万福,姚程源,曲正,武飞宇,胡晓东,胡小唐,旋涂工艺光谱监测系统控制软件,2020SR1050544;
论文、专著
  1. 1. G.T. Ma, W.F. Shen*, S. D. Sanchez, Y. Yu, L.D. Sun, C.G. Hu*. Ultrasensitive in-plane excitons-dominated pseudo-Brewster angle of transition metal dichalcogenides monolayers. Applied Surface Science, 2023, 630: 157493.
  2. 2. W.F. Shen, Z.Y. Sun, S.C. Huo, C.G. Hu*. Direct Evaluating Optical Anisotropy of Few-layered Black Phosphorus during Ambient Oxidization. Advanced Optical Materials, 2022, 10(6): 2102018.
  3. 3. W.F. Shen#, Y. Yu#, Y.F. Huang, G.T. Ma, C.Y. Yao, L.D. Sun, C.G. Hu*.Origins and cavity-based regulation of optical anisotropy of α-MoO3 crystal. 2D materials,2022, 10(1): 015024.
  4. 4. Y. Yu#, W.F. Shen#*, G.T. Ma, Q.Q. Luo, Y.F. Huang, H.Q. Lu, H.L. Wang, L.D. Sun, C.G. Hu*. Anomalous narrow-band optical anisotropy of MoO2 crystal in the visible regime. Applied Physics Letters, 2022, 121(26).
  5. 5. G.T. Ma, W.F. Shen,* S.D. Sanchez, Y. Yu, C.G. Hu*, L.D. Sun. Synthesis and ellipsometric characterizations of large-scale MoS2 sub-monolayer. Thin Solid Films, 2022, 762: 139562.
  6. 6. Y.J. Chen#, Y.K. Wang#, W.F. Shen#, M.H. Wu, B. Li, Q. Zhang, S. Liu, C.G. Hu, S.X. Yang*, Y.N. Gao*, and C.B Jiang*. Strain and Interference Synergistically Modulated Optical and Electrical Properties in ReS2/Graphene Heterojunction Bubbles [J]. ACS Nano, 2022, 16(10): 16271-16280.
  7. 7. P. Li#*, Z.K. Zhang, W.T. Shen, C.G. Hu, W.F. Shen*, and D.Z. Zhang*. A self-powered 2D-material sensor unit driven by a SnSe piezoelectric nanogenerator [J].Journal of Materials Chemistry A, 2021, 9: 4716-4723
  8. 8. W.F. Shen, Y.X. Wei, C.G. Hu, C.B.Lopez-Posadas, M. Hohage, L.D. Sun*. Substrate Induced Optical Anisotropy in Monolayer MoS2,The Journal of Physical Chemistry C, 2020, 124(28): 15468-15473.
  9. 9. W.F. Shen, C.G. Hu*, J. Tao, J. Liu, S.Q. Fan, Y.X. Wei, C.H. An, J.C. Chen, S. Wu, Y.N. Li, J. Liu, D.H. Zhang, L.D. Sun, X.T Hu. Resolving the Optical Anisotropy of Low-Symmetry 2D Materials [J]. Nanoscale, 10 (17), 8329 (2018).
  10. 10. W.F. Shen, C.G. Hu*, S.C. Huo, Z.Y. Sun, S.Q. Fan, J. Liu, X.T. Hu. Wavelength Tunable Polarizer Based on Layered Black Phosphorus on Si/SiO2 Substrate [J]. Optics Letters, 43 (6), 1255 (2018).
  11. 11. W.F. Shen, C.G. Hu*, S. Li, X.T. Hu. Using High Numerical Aperture Objective Lens in Micro-Reflectance Difference Spectrometer [J]. Applied Surface Science, 421,535 (2017).
  12. 12. 10.W.F. Shen, C.G. Hu*, S.C. Huo, Z.Y. Sun, G.F. Fang, J. Liu, L.D. Sun, X.T. Hu. Black Phosphorus Nano-Polarizer with High Extinction Ratio in Visible and Near-Infrared Regime [J]. Nanomaterials, 9(2): 168 (2019).
  13. 13. S.X. Yang#, C.G. Hu#, M.H. Wu#, W.F. Shen#, S. Tongay, K.D. Wu, B. Wei, Z.Y. Sun, C.B. Jiang*, L. Huang*, Z.C. Wang*. In-Plane Optical Anisotropy and Linear Dichroism in Low-Symmetry Layered TlSe [J]. ACS Nano, 12(8): 8798 (2018).
  14. 14. S.X. Yang#*, M.H. Wu#, W.F. Shen#, L. Huang, S. Tongay, K.D. Wu, B. Wei, Y. Qin, Z.C. Wang, C.B. Jiang, C.G. Hu*. Highly Sensitive Polarization Photodetection Using Pseudo-one-dimensional Nb (1-x) TixS3 Alloy [J]. ACS applied materials & interfaces, 11(3): 3342-3350.(2019).
  15. 15. C.Y. Yao, W.F. Shen, X.D. Hu, C.G. Hu*. Evaluation of the surface and subsurface evolution of single-crystal yttrium aluminum garnet during polishing. Applied Surface Science, 2023, 608: 155219.
  16. 16. J.T. Zhang#, T.N. Zhang#, L. Yan#, C. Zhu, W.F. Shen, C.G. Hu, H.X.Lei, H. Luo, D.H Zhang, F.C. Liu, Z. Liu, J.C. Tong*, L.J. Zhou*, P. Yu*, G.W. Yang. Colossal Room‐Temperature Terahertz Topological Response in Type‐II Weyl Semimetal NbIrTe4[J]. Advanced Materials, 2022, 34(42): 2204621.
  17. 17. T.Y. Wang, K. Zhao, P. Wang, W.F. Shen, H.K. Gao, Z.S. Qin, Y.S. Wang, C.L. Li, H.X Deng, C.G. Hu, L. Jiang, H.L. Dong*, Z.M. Wei*, L.Q. Li*, W.P. Hu*. Intrinsic Linear Dichroism of Organic Single Crystals toward High-Performance Polarization-Sensitive Photodetectors[J]. Advanced Materials, 2022, 34(22): 2105665.
  18. 18. R.X. Bai, T. Xiong, J.S. Zhou, Y.Y. Liu, W.F. Shen, C.G. Hu, F.G. Yan, K.Y. Wang, D.H. Wei, J.B. Li, J.H. Yang*, Z.M. Wei. Polarization‐sensitive and wide‐spectrum photovoltaic detector based on quasi‐1D ZrGeTe4 nanoribbon[J]. InfoMat, 2022, 4(3): e12258.
  19. 19. Y.C. Yuan, C.Y. Yao*, W.F. Shen, X.D. Hu, C.G. Hu*. Polarization measurement method based on liquid crystal variable retarder (LCVR) for atomic thin film thickness. Nanomanufacturing and Metrology, 2022, 159-166.
  20. 20. P.Y. Li, J.T. Zhang, C. Zhu, W.F. Shen, C.G. Hu, W.Fu, L. Yan, L.J. Zhou, L. Zheng, H.X. Lei, Z. Liu, W.N. Zhao*, P.Q. Gao*, P. Yu*, and G.W. Yang. Penta‐PdPSe: a new 2D pentagonal material with highly in‐plane optical, electronic, and optoelectronic anisotropy[J]. Advanced Materials, 2021, 33(35): 2102541.
  21. 21. J.W Su, W.F. Shen, J.Z Chen, S.J. Yang, J. Liu, X. Feng, Y.H. Zhao, C.G. Hu, H.Q. Li and T.Y. Zhai*. 2D ternary vanadium phosphorous chalcogenide with strong in-plane optical anisotropy[J]. Inorganic Chemistry Frontiers, 2021, 8(12): 2999-3006.
  22. 22. C.Y. Yao, W.F. Shen, X.D. Hu, C.G. Hu*. Optical properties of large-size and damage-free polished Lu2O3 single crystal covering the ultraviolet-visible-and near-infrared (UV-VIS-NIR) spectral region [J]. Journal of Alloys and Compounds, DOI:10.1016/j.jallcom.2021.16
  23. 23. S.J. Hou, Z.F. Guo, J.H. Yang, Y.Y. Liu, W.F. Shen, C.G. Hu, S.Y. Liu, H.G. Gu*, and Z.M. Wei*. Birefringence and dichroism in quasi‐1D transition metal trichalcogenides: direct experimental investigation [J]. Small, 2021, 17(21): 2100457
  24. 24. C.Y. Yao, S.C. Huo*, W.F. Shen, Z.Y. Sun, X.D. Hu, X.T. Hu, C.G. Hu*. Assessing the quality of polished brittle optical crystal using quasi-Brewster angle technique [J]. Precision Engineering,2021, 72: 184-191.
  25. 25. N. Zuo, A.M. Nie, C.G. Hu, W.F. Shen, B. Jin, X.Z. Hu, Z.Y. Liu, X. Zhou*, T.Y. Zhai. Synergistic Additive‐Assisted Growth of 2D Ternary In2SnS4 with Giant Gate‐Tunable Polarization‐Sensitive Photoresponse [J]. Small, 17(18): 2008078 (2021).
  26. 26. S.C. Huo, H. Wang, C.G. Hu*, C.Y. Yao, W.F. Shen, X.D. Hu, X.T. Hu. Measuring the multilayer silicon based microstructure using differential reflectance spectroscopy [J]. Optics Express, 29(3): 3114-3122 (2021).
  27. 27. K. Zhao, J.H. Yang, M.Z. Zhong, Q. Gao, Y. Wang, X.T. Wang, W.F. Shen, C.G. Hu, K.Y. Wang, G.Z. Shen, M. Li, J.L. Wang, W.D. Hu, and Z.M. Wei*. Direct Polarimetric Image Sensor and Wide Spectral Response Based on Quasi‐1D Sb2S3 Nanowire[J]. Advanced Functional Materials, 2021, 31(6): 2006601.
  28. 28. C.Y. Yao, W.F. Shen, X.D. Hu, C.G. Hu*. Surface and subsurface quality assessment of polished Lu2O3 single crystal using quasi-Brewster angle technique. Frontiers in Physics, 2021, 9: 795639.
  29. 29. C.G. Hu, H. Wang, Y.T. Shen, S.C. Huo*, W.F. Shen, X.D. Hu, X.T Hu. Imaging layer thickness of large-area graphene using reference-aided optical differential reflection technique [J]. Optics Letters, 45(15): 4136-4139 (2020).
  30. 30. M.Z. Zhong, H.T. Meng, S.J. Liu, H. Yang, W.F. Shen, C.G. Hu, J.H Yang, Z.H. Ren, B. Li, Y.Y. Liu, J. He*, Q.L. Xia*, J.B. Li, and Z.M. Wei*. In-plane optical and electrical anisotropy of 2D black arsenic[J]. ACS Nano, 2021, 15(1): 1701-1709.
  31. 31. L.J. Pi, C.G. Hu, W.F. Shen, L. Li, P. Luo, X.Z. Hu, P. Chen, D.Y. Li, Z.X. Li, X. Zhou* and T.Y. Zhai. Highly in‐plane anisotropic 2D PdSe2 for polarized photodetection with orientation selectivity[J]. Advanced Functional Materials, 2021, 31(3): 2006774.
  32. 32. M.Q. Xiao, H. Yang, W.F. Shen, C.G. Hu, K. Zhao, Q. Gao, L.F. Pan, L.Y. Liu, C.L. Wang, G.Z. Shen, H.X. Deng, H.Y. Wen, and Z.M. Wei*. Symmetry‐Reduction Enhanced Polarization‐Sensitive Photodetection in Core–Shell SbI3/Sb2O3 van der Waals Heterostructure[J]. Small, 2020, 16(7)
奖励、荣誉和学术兼职
  1. 天津市优秀博士论文,2023
  2. 本科生毕业设计(论文)优秀指导教师,2022
  3. 2021年第四届低维材料应用与标准研讨会优秀报告,2021
  4. 天津大学优秀博士论文,2019
  5. 国家公派留学奖学金,2018
  6. 欧亚太平洋大学联盟奖学金,2017
 

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