Simultaneous thermal camouflage and radiative cooling for ultrahigh-temperature objects using inversely designed hierarchical metamaterial

IF 6.5 2区 物理与天体物理 Q1 MATERIALS SCIENCE, MULTIDISCIPLINARY
Saichao Dang, Wei Yang, Jialei Zhang, Qiwen Zhan, Hong Ye
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Abstract

Sophisticated infrared detection technology, operating through atmospheric transmission windows (usually between 3 and 5 μm and 8–13 μm), can detect an object by capturing its emitted thermal radiation, posing a threat to the survival of targeted objects. As per Wien’s displacement law, the shift of peak wavelength towards shorter wavelengths as blackbody temperature rises, underscores the significance of the 3–5 μm range for ultra-high temperature objects (e.g., at 400 °C), emphasizing the crucial need to control this radiation for the objects’ viability. Additionally, effective heat management is essential for ensuring the consistent operation of these ultrahot entities. In this study, based on a database with high-temperature resist materials, we introduced a material-informatics-based framework aimed at achieving the inverse design of simultaneous thermal camouflage (low emittance in the 3–5 μm range) and radiative cooling (high emittance in the non-atmospheric window 5–8 μm range) tailored for ultrahigh-temperature objects. Utilizing the transfer matrix method to calculate spectral properties and employing the particle swarm optimization algorithm, two optimized multilayer structures with desired spectral characteristics are obtained. The resulted structures demonstrate effective infrared camouflage at temperatures up to 250 °C and 500 °C, achieving reductions of 86.7 % and 63.7 % in the infrared signal, respectively. At equivalent heating power densities applied to the structure and aluminum, structure 1 demonstrates a temperature reduction of 29.4 °C at 0.75 W/cm2, while structure 2 attains a temperature reduction of 57.5 °C at 1.50 W/cm2 compared to aluminum, showcasing enhanced radiative cooling effects. This approach paves the way for attenuating infrared signals from ultrahigh-temperature objects and effectively managing their thermal conditions.
利用反向设计的分层超材料同时实现超高温物体的热伪装和辐射冷却
先进的红外探测技术可通过大气透射窗口(通常在 3 至 5 微米和 8 至 13 微米之间),捕捉物体发出的热辐射,从而探测到物体,对目标物体的生存构成威胁。根据维恩位移定律,随着黑体温度的升高,峰值波长会向更短的波长移动,这就突出了 3-5 μm 范围对超高温物体(如 400 °C 时)的重要性,强调了控制这种辐射对物体生存的关键必要性。此外,有效的热管理对于确保这些超高温物体的稳定运行也至关重要。在这项研究中,我们以高温抗蚀材料数据库为基础,引入了一个基于材料信息学的框架,旨在实现同时热伪装(3-5 μm 范围内的低幅射)和辐射冷却(5-8 μm 非大气窗口范围内的高幅射)的逆向设计,为超高温物体量身定制。利用传递矩阵法计算光谱特性,并采用粒子群优化算法,获得了两种具有理想光谱特性的优化多层结构。结果表明,在温度高达 250 ℃ 和 500 ℃ 的情况下,这两种结构能有效地进行红外伪装,红外信号分别减少了 86.7% 和 63.7%。在对结构和铝施加相同的加热功率密度时,结构 1 在 0.75 W/cm2 的条件下温度降低了 29.4 °C,而结构 2 在 1.50 W/cm2 的条件下温度比铝降低了 57.5 °C,显示出更强的辐射冷却效果。这种方法为衰减来自超高温物体的红外信号并有效管理其热条件铺平了道路。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
Nanophotonics
Nanophotonics NANOSCIENCE & NANOTECHNOLOGY-MATERIALS SCIENCE, MULTIDISCIPLINARY
CiteScore
13.50
自引率
6.70%
发文量
358
审稿时长
7 weeks
期刊介绍: Nanophotonics, published in collaboration with Sciencewise, is a prestigious journal that showcases recent international research results, notable advancements in the field, and innovative applications. It is regarded as one of the leading publications in the realm of nanophotonics and encompasses a range of article types including research articles, selectively invited reviews, letters, and perspectives. The journal specifically delves into the study of photon interaction with nano-structures, such as carbon nano-tubes, nano metal particles, nano crystals, semiconductor nano dots, photonic crystals, tissue, and DNA. It offers comprehensive coverage of the most up-to-date discoveries, making it an essential resource for physicists, engineers, and material scientists.
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