[1] M Onoda, S Murakami, N Nagaosa. Hall effect of light. Physical Review Letters, 93, 083901(2004).

[2] X Yin, Z Ye, J Rho, et al. Photonic spin hall effect at metasurfaces. Science, 339, 1405-1407(2013).

[3] M V Berry. Quantal phase factors accompanying adiabatic changes. Proceedings of the Royal Society of London. A. Mathematical and Physical Sciences, 392, 45-57(1984).

[4] M V Berry. The adiabatic phase and pancharatnam′s phase for polarized light. Journal of Modern Optics, 34, 1401-1407(1987).

[5] O Hosten, P Kwiat. Observation of the spin hall effect of light via weak measurements. Science, 319, 787-790(2008).

[6] K Y Bliokh, A Niv, V Kleiner, et al. Geometrodynamics of spinning light. Nature Photonics, 2, 748-753(2008).

[7] Q Chu, Y Shen, M Yuan, et al. Numerical simulation and optimal design of segmented planar imaging detector for electro-optical reconnaissance. Optics Communications, 405, 288-296(2017).

[8] M K Manhard, J Stockmann, C Liao, et al. A multi‐inversion multi‐echo spin and gradient echo echo planar imaging sequence with low image distortion for rapid quantitative parameter mapping and synthetic image contrasts. Magnetic Resonance in Medicine, 86, 866-880(2021).

[9] Yilin Wang, Qingbin Fan, Ting Xu. Progress of advanced imaging applications based on electromagnetic metalens. Infrared and Laser Engineering, 50, 20211026(2021).

[10] M Gharghi, C Gladden, T Zentgraf, et al. A carpet cloak for visible light. Nano Letters, 11, 2825-2828(2011).

[11] X Tian, J Xu, K Xu, et al. Phase-change reconfigurable metasurface for broadband, wide-angle, continuously tunable and switchable cloaking. Optics Express, 29, 5959-5971(2021).

[12] X Tian, J Xu, T H Xiao, et al. Broadband generation of polarization-Immune cloaking via a hybrid phase-change metasurface. Photonics, 9, 156(2022).

[13] R Zhao, L Huang, Y Wang. Recent advances in multi-dimensional metasurfaces holographic technologies. PhotoniX, 1, 1-24(2020).

[14] Haoran Mo, Zitao Ji, Yidong Zheng, et al. Broadband achromatic imaging with metalens (Invited). Infrared and Laser Engineering, 50, 20211005(2021).

[15] Kai Ou, Feilong Yu, Jin Chen, et al. Research progress of broadband achromatic infrared metalens (Invited). Infrared and Laser Engineering, 50, 20211003(2021).

[16] X Ling, X Zhou, X Yi, et al. Giant photonic spin hall effect in momentum space in a structured metamaterial with spatially varying birefringence. Light: Science & Applications, 4, e290(2015).

[17] Z Liu, H Du, Z Y Li, et al. Invited Article: Nano-kirigami metasurfaces by focused-ion-beam induced close-loop transformation. APL Photonics, 3, 100803(2018).

[18] P Ding, Y Li, L Shao, et al. Graphene aperture-based metalens for dynamic focusing of terahertz waves. Optics Express, 26, 28038-28050(2018).

[19] J Xu, X Tian, P Ding, et al. Ge₂Sb₂Se₄Te₁-based multifunctional metalenses for polarization-independent, switchable and dual-mode focusing in the mid-infrared region. Optics Express, 29, 44227-44238(2021).

[20] T Li, X Li, S Yan, et al. Generation and conversion dynamics of dual bessel beams with a photonic spin-dependent dielectric metasurface. Physical Review Applied, 15, 014059(2021).

[21] Y Zhang, J B Chou, J Li, et al. Broadband transparent optical phase change materials for high-performance nonvolatile photonics. Nature communications, 10, 4279(2019).

[22] L Tang, R Jin, Y Cao, et al. Spin-dependent dual-wavelength multiplexing metalens. Optics Letters, 45, 5258-5261(2020).

[23] R Jin, L Tang, J Li, et al. Experimental demonstration of multidimensional and multifunctional metalenses based on photonic spin hall effect. ACS Photonics, 7, 512-518(2020).

[24] Y Jia. Focal shift in metasurface based lenses. Optics Express, 26, 8001-8015(2018).

[25] X Tian, J Xu, K Xu, et al. Wavelength-selective, tunable and switchable plasmonic perfect absorbers based on phase change materials Ge₂Sb₂Te₅. EPL (Europhysics Letters), 128, 67001(2020).