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Temperature-adaptive structure with angularly asymmetric emission for thermal management on building vertical surfaces

Author

Listed:
  • Tian, Xuefeng
  • Wang, Jie
  • Wang, Huaiyuan
  • Lu, Yuanwei
  • Zhang, Baiqi
  • Liu, Hanchi
  • Wang, Jiayao
  • Qi, Tao
  • Wang, Meiqi
  • Qu, Zhibin
  • Zhou, Wei
  • Sun, Fei
  • Gao, Jihui
  • Zhao, Guangbo

Abstract

The high solar reflectance of radiative coolers increases winter heating demand, and their fixed-angle emission ignores complex radiative exchange with the ground and surroundings. Here, a temperature-adaptive angularly asymmetric (TAAS) structure with angularly asymmetric emission and dual-band spectral regulation is developed to enable all-season thermal management. The structure adopts a fin-like geometry to realize angularly asymmetric emission. Integrating shape memory alloys (SMAs) and thermochromic microcapsules (TCMs) to achieve independent yet coordinated regulation of mid-infrared radiation and solar spectrum. In hot weather, an upward equivalent emissivity of 0.36, a downward equivalent emissivity of 0.07 and a high solar reflectance (0.91) can be achieved. While in cold weather, a lower equivalent emissivity of 0.13 and higher solar absorption can be realized (0.43). Compared to PDRC film, the TAAS structure enables a temperature decrease of approximately 2 °C in hot weather and a temperature increase of around 5 °C in cold weather. Our design can significantly reduce year-round energy consumption by 1.4–6.3 % and outperforms conventional building envelopes under various weather conditions. This structure advances the concept from static radiative cooling to adaptive thermal management, offering a practical solution for all-season thermal management on building vertical surfaces.

Suggested Citation

  • Tian, Xuefeng & Wang, Jie & Wang, Huaiyuan & Lu, Yuanwei & Zhang, Baiqi & Liu, Hanchi & Wang, Jiayao & Qi, Tao & Wang, Meiqi & Qu, Zhibin & Zhou, Wei & Sun, Fei & Gao, Jihui & Zhao, Guangbo, 2026. "Temperature-adaptive structure with angularly asymmetric emission for thermal management on building vertical surfaces," Renewable Energy, Elsevier, vol. 259(C).
  • Handle: RePEc:eee:renene:v:259:y:2026:i:c:s0960148125027508
    DOI: 10.1016/j.renene.2025.125086
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    References listed on IDEAS

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    1. Dongpyo Hong & Yong Joon Lee & Ok Sung Jeon & In-Sung Lee & Se Hun Lee & Jae Yeon Won & Young Pyo Jeon & Yunju La & Seonmyeong Kim & Gun-Sik Park & Young Joon Yoo & Sang Yoon Park, 2024. "Humidity-tolerant porous polymer coating for passive daytime radiative cooling," Nature Communications, Nature, vol. 15(1), pages 1-11, December.
    2. Li, Yunhe & Zhang, Xun & Chen, Yixiang & Zhang, Siqi & Liu, Yanghang & Yu, Dan & Wang, Wei, 2025. "Polar bear fur-inspired hollow nanofibers as a thermal insulating material for building radiation cooling," Renewable Energy, Elsevier, vol. 250(C).
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