Gender: Male
Title: Special Researcher/Associate Professor
Education: Doctoral student
Discipline: Optical Engineering
Research interests: Surface plasmon, Metamaterials, Metasurface Devices, Graphene photonic Devices, Micro-nano Optics, full Vector Diffraction Algorithm
E-mail: hubin@bit.edu.cn
I. Personal Profile

Hu Bin, male, was born in April 1981 in Hebei Province. Doctor, pre-appointed associate professor, School of Optoelectronics, Beijing Institute of Technology. His major is Optical Engineering, and his main research direction is micro and nano optics. He received his Ph.D. from the Institute of Microelectronics, Chinese Academy of Sciences, and did postdoctoral research at Nanyang Technological University, Singapore. The research involves the fields of super-resolution imaging based on surface plasmon polaritons and metamaterials, surface plasma micro-nano optics based on two-dimensional materials, magnetic surface plasmon physical properties and devices, biosensing based on metal nanoparticles surface plasmon enhancement, full vector diffraction algorithm and so on. In 2013, he joined the School of Optoelectronics of Beijing Institute of Technology and was funded by the New Century Talent Support Program of the Ministry of Education in the same year. Presided over and undertook a number of provincial and ministerial level projects, including natural fund projects, national key research and development projects. He has published more than 50 articles in the world-famous optical and physics journals Opt.Lett., Opt.Express, Appl.Phys. Lett., Nanotechnology. Main courses: Physical optics, basic programming, micro and nano optics, etc. Undertook 2 teaching research and reform projects. There are 4 doctoral students, 3 international students and 6 master students. As the responsible editor of "Optical Technology", is the reviewer of PTL, EPL and other international journals.

1. Terahertz imaging and communication;
2. Laser-induced graphene;
3. Graphene-based wavefront modulators;
4. Metasurface and Metamaterial Design;
5. Diffractive optics;
6. Full Vector Diffraction algorithm;

1.  B. Deng, Z. Wang, W. Liu, J. Zhang, and B. Hu*, "Stretchable terahertz metasurface based on laser induced graphene for contactless deformation sensing," Opt. Express 32(17), 29740 (2024).
2.  C. Xiong, X. Wu, J. Huang, J. Zhang, and B. Hu*, "Terahertz optical pattern recognition with rotation and scaling enhanced by a 3D-printed diffractive deep neural network," Opt. Express 32(16), 27635 (2024).
3.  M. Qasim, M. Sulaman, A. Jalal, S. Yang, A. Imran, N. Jafar, C. Li, M. Ali, M. Abbas, N. H. Shah, A. Bukhtiar, and B. Hu, "Scalable flexible and stretchable high performance UV photodetector based on MoS2-WO3/Ag composite on a PU substrate by utilizing LIG electrodes," Journal of Alloys and Compounds 993, 174652 (2024).
4.  Z. Wang, J. Huang, W. Liu, C. Xiong, and B. Hu, "Automatically Aligned and Environment-Friendly Twisted Stacking Terahertz Chiral Metasurface with Giant Circular Dichroism for Rapid Biosensing," ACS Appl. Mater. Interfaces 16(12), 15193–15201 (2024).
5.  M. Qasim, A. Jalal, M. Sulaman, S. Yang, A. Imran, J. Huang, M. A. Rasheed, N. H. Shah, C. Li, A. Bukhtiar, and H. Bin, "Cost‐Effective and Flexible Scalable Fabrication of WO 3 UV Photodetectors with Enhanced Performance via Integrated LIG Electrodes," Adv Materials Technologies 2301650 (2024).
6.  U. U. R. Qureshi, B. Hu, S. Basir, M. Ahmad, A. Jalal, and M. Ismail Khan, "Design and experimental realization of multifunctional anisotropic metasurface for efficient polarization manipulation in microwave frequencies," Phys. Scr. 99(1), 015512 (2023).
7.  G. Wang, B. Hu, H. Zhao, M. Xu, X. Wang, J. Ye, W. Sun, S. Feng, P. Han, X. Wang, B. Zhang, and Y. Zhang, "Pump‐Wavelength Sensitive Terahertz Spatiotemporal Metasurface," Advanced Optical Materials 2301994 (2023).
8.  M. Moghaddasi, B. Hu, and F. Abrinaei, "Highly robust performance of a compact, wide-angle, nano-optic capsule endoscopy camera," J. Opt. Soc. Am. A 40(12), 2298 (2023).
9.  U. U. R. Qureshi, B. Hu, M. Ahmad, and A. Jalal, "Graphene-Based Triple-Band Tunable Metasurface with Strong Circular Dichroism for Hz Communication," IEEE Photon. Technol. Lett. 1–1 (2023).
10.  A. Jalal, M. Qasim, U. U. R. Qureshi, and B. Hu, "Active anisotropic polarization conversion meta-surface for 6G communication bandgap in the reflection mode," Phys. Scr. 98(11), 115514 (2023).
11.  U. U. R. Qureshi, B. Hu, M. I. Khan, and M. Ahmad, "Multifunctional active terahertz metasurface with electromagnetically induced transparency, perfect absorption, and circular dichroism," Optics Communications 129989 (2023).
12.  B. Deng, Z. Wang, W. Liu, and B. Hu, "Multifunctional Motion Sensing Enabled by Laser-Induced Graphene," Materials 16, 6363 (2023).
13.  Y. Dong, Z. Wang, C. Xiong, B. Deng, and B. Hu, "Printable and low-cost perfect terahertz absorber realized by a laser-induced graphene metasurface," Opt. Lett. 48(19), 5009 (2023).
14.  B. Hu, Q. J. Wang, and Y. Zhang, "Systematic study of the focal shift effect in planar plasmonic slit lenses," Nanotechnology 23(44), 444002 (2012).
15.  J. Huang, B. Hu, J. Liu, Y. Zhang, G. Wang, Z. Wang, and J. Li, "BICs-enhanced active terahertz wavefront modulator enabled by laser-cut graphene ribbons," Photonics Research 11(7), 1185–1195 (2023).
16.  A. Jalal, M. I. Khan, M. Qasim, and B. Hu, "Multifunctional and switchable metamaterial for terahertz polarization modulation in the reflection mode," J. Opt. Soc. Am. A 40(6), 1183 (2023).
17.  Z. Wang, B. Hu, J. Liu, G. Wang, W. Liu, C. Xiong, J. Huang, J. Liu, and Y. Zhang, "4f‐Less Terahertz Optical Pattern Recognition Enabled by Complex Amplitude Modulating Metasurface Through Laser Direct Writing," Advanced Optical Materials 11(19), 2300575 (2023).
18.  M. I. Khan, B. Hu, Y. Chen, N. Ullah, M. J. I. Khan, and A. R. Khalid, "Multiband Efficient Asymmetric Transmission With Polarization Conversion Using Chiral Metasurface," Antennas Wirel. Propag. Lett. 19(7), 1137–1141 (2020).
19.  Z. Du, B. Hu, W. Liu, J. Liu, and Y. Wang, "Tunable beam deflector by mutual motion of cascaded bilayer metasurfaces," J. Opt. 21(11), 115101 (2019).
20.  Z. Liu, Z. Du, B. Hu, W. Liu, J. Liu, and Y. Wang, "Wide-angle Moiré metalens with continuous zooming," J. Opt. Soc. Am. B 36(10), 2810 (2019).
21.  W. Liu, B. Hu, Z. Du, Z. Wang, X. Zhou, J. Liu, and Y. Wang, "Enhanced Electric Tuning of Raman Scattering in Monolayer Graphene by Gold NanoRods," Plasmonics 13(1), 275–280 (2018).
22.  W. Liu, B. Hu, Z. Huang, H. Guan, H. Li, X. Wang, Y. Zhang, H. Yin, X. Xiong, J. Liu, and Y. Wang, "Graphene-enabled electrically controlled terahertz meta-lens," Photon. Res. 6(7), 703 (2018).
23.  Z. Du, B. Hu, W. Liu, J. Tao, J. Liu, and Y. Wang, "Plasmonic resonance of distorted graphene nano-ribbon analyzed by boundary element method," Opt. Express 26(20), 25962 (2018).
24.  Z. Du, B. Hu, P. Cyril, J. Liu, and Y. Wang, "High sensitivity plasmonic sensor using hybrid structure of graphene stripe combined with gold gap-ring," Mater. Res. Express 4(10), 105013 (2017).
25.  Z.-Y. Du, B. Hu, F.-L. Ma, and J. Liu, "Local Field Enhancement Tuning of Horseshoe-Shaped Nanoparticles," in Asia Communications and Photonics Conference 2016 (OSA, 2016), p. ATh3K.3.
26.  Z. Huang, B. Hu, W. Liu, J. Liu, and Y. Wang, "Dynamical tuning of terahertz meta-lens assisted by graphene," J. Opt. Soc. Am. B 34(9), 1848 (2017).
27.  B. Hu and J. Liu, "Micro- and nano-photonics course in Beijing Institute of Technology," in 14th Conference on Education and Training in Optics and Photonics: ETOP 2017, X. Liu and X.-C. Zhang, eds. (SPIE, 2017), p. 158.
28.  Liu Weiguang 刘伟光, Hu Bin 胡滨, Li Biao 李彪, Liu Juan 刘娟, and Wang Yongtian 王涌天, "Research Progress of Optical Modulator Based on Graphene-Metal Composite Structures," Laser Optoelectron. Prog. 53(3), 030005 (2016).
29.  B. Li, B. Hu, Y. Yang, Z. Wang, J. Liu, and Y. Wang, "Demagnification Imaging Improved by Mask in a Hyperlens Photolithography System," Plasmonics 12(3), 735–741 (2017).
30.  Z. Wang, B. Hu, B. Li, W. Liu, X. Li, J. Liu, and Y. Wang, "Active focal control of an ultrathin graphene-metal metasurface lens," Mater. Res. Express 3(11), 115011 (2016).
31.  B. Hu, Y. Zhang, and Q. J. Wang, "Surface magneto plasmons and their applications in the infrared frequencies," Nanophotonics 4(4), 383–396 (2015).
32.  B. Hu, J. Tao, Y. Zhang, and Q. J. Wang, "Magneto-plasmonics in graphene-dielectric sandwich," Opt. Express 22(18), 21727 (2014).
33.  J. Tao, X. Yu, B. Hu, A. Dubrovkin, and Q. J. Wang, "Graphene-based tunable plasmonic Bragg reflector with a broad bandwidth," Opt. Lett. 39(2), 271 (2014).
34.  B. Hu, Q. J. Wang, and Y. Zhang, "Broadly tunable one-way terahertz plasmonic waveguide based on nonreciprocal surface magneto plasmons," Opt. Lett. 37(11), 1895 (2012).
35.  B. Hu, Q. J. Wang, and Y. Zhang, "Voigt Airy surface magneto plasmons," Opt. Express 20(19), 21187 (2012).
36.  B. Hu, Q. J. Wang, and Y. Zhang, "Slowing down terahertz waves with tunable group velocities in a broad frequency range by surface magneto plasmons," Opt. Express 20(9), 10071 (2012).
37.  B. Hu, Q. J. Wang, S. W. Kok, and Y. Zhang, "Active Focal Length Control of Terahertz Slitted Plane Lenses by Magnetoplasmons," Plasmonics 7(2), 191–199 (2012).
38.  B. Hu, B.-Y. Gu, B.-Z. Dong, Y. Zhang, and M. Liu, "Various evaluations of a diffractive transmitted field of light through a one-dimensional metallic grating with subwavelength slits," Open Physics 8(3), (2010).
39.  B. Hu, B.-Y. Gu, Y. Zhang, and M. Liu, "Transmission interference tuned by an external static magnetic field in a two-slit structure," Appl. Phys. Lett. 95(12), 121103 (2009).
40.  B. Hu, B.-Y. Gu, B.-Z. Dong, and Y. Zhang, "Optical transmission resonances tuned by external static magnetic field in an n-doped semiconductor grating with subwavelength slits," Optics Communications 281(24), 6120–6123 (2008).
41.  B. Hu, B.-Y. Gu, B.-Z. Dong, and Y. Zhang, "Transmission resonances of two-constituent metal/dielectric gratings with subwavelength slits," Appl. Phys. Lett. 92(15), 151901 (2008).
42.  S. Wang, J. Liu, B. Gu, Y. Wang, B. Hu, X. Sun, and S. Di, "Rigorous electromagnetic analysis of the common focusing characteristics of a cylindrical microlens with long focal depth and under multiwavelength illumination," J. Opt. Soc. Am. A 24(2), 512 (2007).
43.  G. Wang, T. Zhou, J. Huang, X. Wang, B. Hu, and Y. Zhang, "Moiré meta-device for flexibly controlled Bessel beam generation," Photon. Res. 11(1), 100 (2023).
44.  Y. Jiang, C. Cui, J. Zhao, and B. Hu, "Mid-Infrared Broadband Achromatic Metalens with Wide Field of View," Materials 15(21), 7587 (2022).
45.  C. Cui, Z. Liu, B. Hu, Y. Jiang, and J. Liu, "A multi-channeled vortex beam switch with moiré metasurfaces," J. Opt. 24(1), 015004 (2022).
46.  Z. Wang, G. Wang, B. Hu, W. Liu, J. Huang, C. Xiong, Y. Zhang, J. Liu, and Y. Wang, "Fast-printed, large-area and low-cost terahertz metasurface using laser-induced graphene," Carbon 187, 256–265 (2022).
47.  U. U. R. Qureshi, M. I. Khan, and B. Hu, "A Theoretical Proposal for an Actively Controlled Ultra-Wideband Absorber Based on Vanadium Dioxide Hybrid Metamaterials," Applied Sciences 12(19), 10164 (2022).
48.  Z. Wang, B. Hu, Z. Niu, W. Liu, G. Wang, and Y. Zhang, "Terahertz surface plasmon polaritons travelling on laser-induced porous graphene," Appl. Phys. Lett. 120(18), 181701 (2022).
49.  Wang Zongyuan 王宗源, Hu Bin 胡滨, and Wu Xudong 吴旭东, "Research Progress of Laser-Induced Graphene Technology," Laser Optoelectron. Prog. 58(1), 0100003 (2021).
50.  T. Zhou, B. Hu, Z. Liu, and J. Liu, "Deflectable Moiré Metalens," Optik 247, 167806 (2021).
51.  Y. Qian, B. Hu, Z. Du, and J. Liu, "Reinforced design method for moiré metalens with large spacing," Opt. Express 29(17), 26496 (2021).
52.  S. Wang, B. Hu, W. Liu, and J. Liu, "Scattered coupling between two wrinkled graphene nanoribbons analyzed by boundary element method," Mod. Phys. Lett. B 35(18), 2150304 (2021).
53.  J. Huang, B. Hu, K. Muhammad Ismail, W. Liu, and J. Liu, "Graphene-enabled active terahertz focusing with wide tuning range," J. Phys. D: Appl. Phys. 54(38), 385104 (2021).
54.  G. Wang, B. Hu, M. I. Khan, and Y. Zhang, "Active Control of the THz Wave Polarization State by an Electronically Controlled Graphene Composite Metasurface," Front. Phys. 9, 751026 (2021).
55.  W. Shuo, H. Bin, L. Juan, 北京理工大学 光电学院，北京 100081, and School of Optics and Photonics, Beijing Institute of Technology, Beijing 100081, China, "Surface plasmon resonance characteristics of a graphene nano-disk based on three-dimensional boundary element method," Chinese Optics 14(5), 1288–1304 (2021).
56.  M. I. Khan, Y. Chen, B. Hu, N. Ullah, S. H. R. Bukhari, and S. Iqbal, "Multiband linear and circular polarization rotating metasurface based on multiple plasmonic resonances for C, X and K band applications," Sci Rep 10(1), 17981 (2020).
57.  Y. Qian, B. Li, L. Min, W. Liu, J. Liu, and B. Hu, "Highly Uniform Plasmonic Interference Lithography Assisted by Hyperbolic Multilayer Graphene," Plasmonics 15(3), 623–629 (2020).
58.  N. Ullah, W. Liu, G. Wang, Z. Wang, A. U. R. Khalid, B. Hu, J. Liu, and Y. Zhang, "Gate-controlled terahertz focusing based on graphene-loaded metasurface," Opt. Express 28(3), 2789 (2020).
59.  J. Huang, H. Guan, B. Hu, G. Wang, W. Liu, Z. Wang, J. Liu, Y. Zhang, and Y. Wang, "Enhanced terahertz focusing for a graphene-enabled active metalens," Opt. Express 28(23), 35179 (2020).
60.  M. I. Khan, Z. Khalid, S. A. K. Tanoli, F. A. Tahir, and B. Hu, "Multiband linear and circular polarization converting anisotropic metasurface for wide incidence angles," J. Phys. D: Appl. Phys. 53(9), 095005 (2020).
61.  N. Ullah, B. Hu, A. U. R. Khalid, H. Guan, M. I. Khan, and J. Liu, "Efficient tuning of linearly polarized terahertz focus by graphene-integrated metasurface," J. Phys. D: Appl. Phys. 53(20), 205103 (2020).
62.  M. I. Khan, B. Hu, A. Amanat, N. Ullah, M. J. I. Khan, and A. R. Khalid, "Efficient asymmetric transmission for wide incidence angles using bi-layered chiral metasurface," J. Phys. D: Appl. Phys. 53(30), 305004 (2020).
63.  Z. Wang, G. Wang, W. Liu, B. Hu, J. Liu, and Y. Zhang, "Patterned laser-induced graphene for terahertz wave modulation," J. Opt. Soc. Am. B 37(2), 546 (2020).
64.  王宗源, 胡滨, and 吴旭东, "激光诱导石墨烯技术研究进展," 激光与光电子学进展 58(1), 0100003 (2021).