Highly efficient flexible structured metasurface by roll-to-roll printing for diurnal radiative cooling

IF 27.2 Q1 OPTICS eLight Pub Date : 2023-10-25 DOI:10.1186/s43593-023-00053-3

Keng-Te Lin, Xianbo Nian, Ke Li, Jihong Han, Nan Zheng, Xiaokang Lu, Chunsheng Guo, Han Lin, Baohua Jia

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引用次数: 1

Abstract

Abstract An ideal radiative cooler requires accurate spectral control capability to achieve efficient thermal emission in the atmospheric transparency window (8–13 μm), low solar absorption, good stability, scalability, and a simple structure for effective diurnal radiative cooling. Flexible cooling films made from polymer relying on polymer intrinsic absorbance represent a cost-effective solution but lack accuracy in spectral control. Here, we propose and demonstrate a metasurface concept enabled by periodically arranged three-dimensional (3D) trench-like structures in a thin layer of polymer for high-performance radiative cooling. The structured polymer metasurface radiative cooler is manufactured by a roll-to-roll printing method. It exhibits superior spectral breadth and selectivity, which offers outstanding omnidirectional absorption/emission (96.1%) in the atmospheric transparency window, low solar absorption (4.8%), and high stability. Impressive cooling power of 129.8 W m −2 and temperature deduction of 7 °C on a clear sky midday have been achieved, promising broad practical applications in energy saving and passive heat dispersion fields.

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高效柔性结构超表面，采用卷对卷印刷，全天候辐射冷却

理想的辐射冷却器要求具有精确的光谱控制能力，在大气透明窗(8 ~ 13 μm)内实现高效的热发射，太阳吸收率低，稳定性好，可扩展性好，结构简单，从而实现有效的日间辐射冷却。利用聚合物固有吸光度制成的柔性冷却膜是一种经济有效的解决方案，但在光谱控制方面缺乏准确性。在这里，我们提出并演示了一种超表面概念，该概念是通过在薄层聚合物中周期性排列的三维(3D)沟槽状结构实现的，用于高性能辐射冷却。该结构聚合物超表面辐射冷却器采用卷对卷印刷方法制造。它具有优异的光谱宽度和选择性，在大气透明窗口内具有出色的全向吸收/发射(96.1%)、低太阳吸收(4.8%)和高稳定性。在晴朗的中午，令人印象深刻的冷却功率达到129.8 W m−2，温度降低7°C，在节能和被动散热领域有广泛的实际应用前景。

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来源期刊

eLight

CiteScore

30.40

自引率

0.00%

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