Issue 29, 2024

In situ switchable nanofiber films based on photoselective asymmetric assembly towards year-round energy saving

Abstract

Thermal management of buildings consumes 51% of the world's energy use. Optimization of the energy use can be potentially achieved via daylight harvesting and radiative cooling approaches, yet their simultaneous utilization under static conditions is challenging due to opposite operation principles. Here, an in situ switchable photoselective polymer (PSP) material was prepared by sequential electrospinning of light-reflecting and light-absorbing layers made of contrasting polymer nanofibers. The as-prepared PSP material exhibited a high solar light reflectance of 97.7% and a high broadband emissivity of 94.9% resulting in a radiative cooling power of 111.1 W m−2. Such “cooling” state of the PSP film can be easily switched to a “heating” one via impregnation of an index matching liquid that suppresses scattering at the film–air interface and reduces the solar band reflectivity of the film. Thanks to the highly porous structure of the designed PSP film, its switching takes less than 5 min and allows an integrated solar absorbance of ∼95.6% to be achieved, resulting in an estimated heating power of 781.6 W m−2. Performed numerical calculations further supported the high potential of the developed PSP film for thermal management of buildings located at high latitudes with energy savings up to 89.74 GJ m−2 per year and reduced CO2 emissions down to 21.69 t.

Graphical abstract: In situ switchable nanofiber films based on photoselective asymmetric assembly towards year-round energy saving

Supplementary files

Article information

Article type
Paper
Submitted
22 พ.ค. 2567
Accepted
14 มิ.ย. 2567
First published
17 มิ.ย. 2567

J. Mater. Chem. A, 2024,12, 18304-18312

In situ switchable nanofiber films based on photoselective asymmetric assembly towards year-round energy saving

L. An, J. Ma, P. Wang, A. Kuchmizhak, J. Yao, H. Xu and W. Wang, J. Mater. Chem. A, 2024, 12, 18304 DOI: 10.1039/D4TA03558E

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