David Osuna Ruiz, Maite Aznarez-Sanado, Pilar Herrera-Plaza, Miguel Beruete
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引用次数: 0
摘要
结合人工智能(AI)方法和电磁仿真软件对多层辐射冷却结构进行了全面的数值研究。最初的结构是由纳米厚度的SiO2/Si层构成的,这些层构成了太阳辐照窗(0.3-4 μm)波长的布拉格反射镜。然后根据计算的净冷却功率对结构进行优化,并通过反射和吸收入射光作为其结构参数的函数来表征结构。该研究提供了超布拉格、全介电、超宽带反射镜的最佳设计,其净冷却功率约为≈100 W m−2,与文献中性能最好的结构相似。此外,它解释了人工智能在生产这些结构方面的成功,并能够分析具有非常规层厚分布的无金属多层中的谐振条件,为RC中高效结构的设计提供创新工具。
Artificial Intelligence-Enhanced Metamaterial Bragg Multilayers for Radiative Cooling
A full numerical study combining artificial intelligence (AI) methods and electromagnetic simulation software on a multilayered structure for radiative cooling (RC) is investigated. The original structure is made of SiO2/Si nanometer-thick layers that make a Bragg mirror for wavelengths in the solar irradiance window (0.3–4 μm). The structures are then optimized in terms of the calculated net cooling power and characterized via the reflected and absorbed incident light as a function of their structural parameters. This investigation provides with optimal designs of beyond-Bragg, all-dielectric, ultra-broadband mirrors that provide net cooling powers in the order of ≈100 W m−2, similar to the best-performing structures in literature. Furthermore, it explains AI's success in producing these structures and enables the analysis of resonant conditions in metal-free multilayers with unconventional layer thickness distributions, offering innovative tools for designing highly efficient structures in RC.
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