[5] D FAYE, J MRACO. Effects of ultraviolet and protons radiations on thermal control coatingsafter contami nation, 527-533(2003).

[6] D A JAWORSKE. Correlation of predicted and observed optical properties of multilayer thermal control coatings. Thin Solid Films, 332, 30-33(1998).

[10] K SUN, C A RIEDEL, Y D WANG et al. Metasurface optical solar reflectors using azo transparent cond ucting oxides for radiative cooling of spacecraft. ACS Photonics, 5, 495-501(2018).

[13] T YAN, D XU, J MENG et al. A review of radiative sky cooling technology and its application in building systems. Renewable Energy, 220, 1-30(2024).

[14] T LI, Y ZHAI, S HE et al. A radiative cooling structural material. Science, 364, 760-763(2019).

[15] M HOSSAIN, M GU. Radiative cooling：principles，progress，and potentials. Advanced Science, 3, 1-10(2016).

[16] S FAN. Thermal photonics and energy applicationsc. Joule, 1, 264-273(2017).

[17] M ZOYSA, T ASANO et al. Conversion of broadband to narrowband thermal emission through energy recycling. Nature Photonics, 535-539(2012).

[18] A RAMAN, M ANOMA, L ZHU et al. Passive radiative cooling below ambient air temperature under direct sunlight. Nature, 515, 540-544(2014).

[19] Y PENG, J LAI, X XIAO et al. Colorful low-emissivity paints for space heating and cooling nenrgy savings. Reserach Article, 120, 1-9(2023).

[20] Y ZHAI, Y MA, N D SABRINA et al. Scalable-manufacturee randomized glass-polymer hubrid metamaterial for daytime radiative cooling. Science, 355, 1062-1066(2017).

[21] X LIU, C XIAO, P WANG et al. Biomimetic photonic multiform composite for high-performance radiative cooling. Advance Optical Material, 9, 3126-3135(2021).

[22] Q YUE, L ZHANG, C HE et al. Polymer composites with hierachical architecture and dielectric partickes for efficient daytime subambient radiative cooling. Journal of Materials Chemistry A, 11, 3126-3135(2023).

[23] Z YAN, G ZHU, D FAN et al. Bioinspired metafabric with dual-gradient janus design for personal radiative and evaporative cooling. Advanced Functional Materials, 34, 1-14(2024).

[24] Q LIU, W WU, S LIN et al. Non-tapered metamaterial emitters for radiative cooling to low temperature limit. Optics Communications, 450, 246-251(2019).

[25] Z CHEN, L ZHU, A RAMAN et al. Radiative cooling to deep sub-freezing temperatures through a 24-h day-night cycle. Nature Communication, 7, 13729-13734(2016).

[26] Q XIE, Y ZHANG, E JANZEN et al. Atomic-force-microscopy-based time-domain two-dimensional infrared nanospectroscopy. Nature Nanotechnology, 19, 1108-1115(2024).

[27] X GUO, N LI, X YANG et al. Hyperbolic whispering-gallery phonon polaritons in boron nitride nanotubes. Nature Nanotechnology, 18, 529-534(2023).

[28] Y ZHAI, Y MA, D SABRINA et al. Scalable-manufactured randomized glass-polymer hybrid metamaterial for daytime radiative cooling. Science, 355, 1062-1066(2017).

[29] D P EDWARD. Handbook of optical constants of solids II(1998).

[30] E REPHAELI, A RAMAN, S FAN. Ultrabroadband photonic structures to achieve high-performance daytime radiative cooling click to copy article link. Nano Letters, 13, 1457-1461(2013).

[31] P LIN, Y LI, T CHENG et al. Coexistence of photonic banggap guidance and total internal reflection in photonic crystal fiber based on a high-index array with internal air holes. IEEE Journal of Selected Topics in Quantum Electronic, 22, 365-270(2016).

[32] K KIM, S PARK. Enhancing light-extraction efficiency of oleds with high-and low-refractive-index organic-inorganic hybrid materials. Organic Electronic, 36, 103-112(2016).

[34] Y LI, R QI, R SHI et al. Manipulation of surface phonon polaritions in sic nanorods. Science Bulletin, 65, 820-826(2020).

[35] L WANG, M WAGNER, H WANG et al. Revealing phonon polaritons in hexagonal boron nitride by multipulse peak force infrared microscopy. Advance Optical Material, 8, 1-6(2019).

[37] X WANG, X LIU, Z LI et al. Scalable flexible hybrid membranes with photonic structures for daytime radiative cooling. Advanced Functional Materials, 30, 1-9(2020).