成人抖音

张侠

发布时间:2025-06-16浏览次数:170

姓名:张侠

职称:副教授

专业:物理学

所属二级学科:光学

研究方向:微纳光学

E-mail: [email protected]

  

  

  

个人简历:本人长期从事微纳光学领域的研究,主要聚焦于光与物质相互作用、等离激元、光子晶体及超构表面等方向。博士毕业于爱尔兰都柏林圣三一学院(Trinity College Dublin)物理系。专业为纳米光子学。2022年入职成人抖音-每日更新热门成人抖音内容 物理系,入选兴辽英才计划博士后储备项目,讲授本科生课程《电动力学》及研究生课程《纳米光子学》。

近年来的主要研究工作:

1.基于全介质超构表面共振的光学调控

2.表面等离激元共振和局域表面等离激元极化激元

3.微纳光腔中光与物质的耦合

近年来承担的主要项目(五项):

1.广东省自然科学基金, 面上项目, Friedrich-Wintgen连续域束缚态的主动形成及强耦合调控, 2025-01-01  2027-12-31, 在研, 主持

2.中央高校基本科研业务专项资金资助,参数调谐连续域束缚态的调控和强耦合特性,20241-202512月,在研, 主持

  

近年来发表的代表性论文(十篇):

  1. Hajian, H., Zhang, X, McCormack, O., Zhang,      Y., Dobie, J., Rukhlenko, I. D., Ozbay, E., & Louise Bradley, A.      (2024). Quasi-bound states in the continuum for electromagnetic induced      transparency and strong excitonic coupling. Optics Express, 32(11),      19163–19174. //doi.org///doi.org/10.1364/OE.525535

2.Zhang, X, Zhang, X, Bradley, A. L. (2023). Supercavity modes in stacked identical Mie-resonant metasurfacesPhysical Review B 108 (19), 195404DOI: //doi.org/10.1103/PhysRevB.108.195404

  1. Zhang, X, & Bradley, A. L. (2022). Polaritonic      Critical Coupling in a Hybrid Quasi-Bound States in the Continuum      Cavity-WS2 Monolayer System. Physical Review B, 165424,      1–7, //doi.org/10.1103/PhysRevB.105.165424

  2. Zhang, X, Lawless, J., Li, J., Peters, L., McEvoy, N.,      Donegan, J. F., & Bradley, A. L. (2022). Absorbance Enhancement of      Monolayer MoS2 in a Perfect Absorbing      System. Physical Review Materials, 045202, 4–9, //doi.org/10.1103/PhysRevMaterials.6.045202

  3. Zhang, X, & Bradley, A. L. (2021). Wide-Angle      Invisible Dielectric Metasurface Driven by Transverse Kerker Scattering. Physical      Review B, 103, 195419. //doi.org/10.1103/PhysRevB.103.195419

  4. Zhang, X, Li, J., Donegan, J. F., & Bradley, A. L.      (2020). Constructive and Destructive Interference of Kerker-type      Scattering in an Ultrathin Silicon Huygens Metasurface. Physical      Review Materials, 4(12), 125202. //doi.org/10.1103/PhysRevMaterials.4.125202

  5. Dlamini, S., Francis, J., Zhang, X, Özdemir, Ş., Chormaic,      S. N., Petruccione, F., & Tame, M. (2018). Probing decoherence in      plasmonic waveguides in the quantum regime. Physical Review Applied,      9(2),024003.//doi.org/10.1103/PhysRevApplied.9.024003

  

  1. Uriri, S., Tashima, T., Zhang, X, Asano, M.,      Bechu, M., Güney, D., Yamamoto, T.,      Özdemir, Ş., Wegener,      M., & Tame, M. (2018). Active control of a plasmonic metamaterial for      quantum state engineering. Physical Review A, 97(5),      053810. //doi.org/10.1103/PhysRevA.97.053810

  2. Zhang, X, Marocico, C. A., Lunz, M., Gerard, V. A.,      Gun’ko, Y. K., Lesnyak, V., Gaponik, N., Susha, A. S., Rogach, A. L.,      & Bradley, A. L. (2014). Experimental and theoretical investigation of      the distance dependence of localized surface plasmon coupled forster      resonance energy transfer. ACS nano, 8(2), 1273–1283.      //doi.org/10.1021/nn406530m

  3. Zhang, X, Marocico, C. A., Lunz, M., Gerard, V. A.,      Gun’ko, Y. K., Lesnyak, V., Gaponik, N., Susha, A. S., Rogach, A. L.,      & Bradley, A. L. (2012). Wavelength, concentration, and distance      dependence of nonradiative energy transfer to a plane of gold nanoparticles.      ACS nano, 6(10), 9283–9290. //doi.org/10.1021/nn303756a