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Biodegradable, scalable and flexible fiber membrane for green passive radiative cooling

Peng Xu, Bo Xiang, Wenhuan Zhong, Yali Wu, Yifan Zhang, Yongsheng Chang, Wen Lei, Rong Zhang

2023Solar Energy Materials and Solar Cells44 citationsDOIOpen Access PDF

Abstract

The passive radiative cooling (PRC) approach allows zero-energy cooling by reflecting solar light and radiating heat simultaneously. However, most of the current PRC materials, especially polymer-based ones, are not able to be naturally degraded in the environment over a short time period when discarded, causing the current white pollution problem. Herein, we demonstrate a novel PRC material based on eco-friendly fiber membrane derived from biomass-derived silk fibroin (SF) and polylactic acid (PLA), which can be quickly degraded in outdoor soil environment for just one month. The resulting SF/PLA fiber membrane achieved ultra-high solar reflectance R ‾ s o l a r and infrared emittance ε ‾ I R of 96.1% and ∼95.4%, respectively, and yielded an average sub-ambient cooling temperature of ∼6 °C even under a peak solar intensity of ∼900 W m −2 owing to its outstanding optical properties . In addition, large-scale products were prepared by simple and cost-effective electrostatic spinning-based manufacturing process. This study offers a new strategy that combines biodegradation with zero-energy cooling and shows great potential for widespread future applications, substantially decreasing energy consumption and carbon emission .

Topics & Concepts

Materials scienceThermal emittanceFiberRadiative coolingPolylactic acidSolar energyRadiative transferEnvironmental scienceOpticsComposite materialPolymerMeteorologyPhysicsBiologyEcologyBeam (structure)Thermal Radiation and Cooling TechnologiesUrban Heat Island MitigationBuilding Energy and Comfort Optimization
Biodegradable, scalable and flexible fiber membrane for green passive radiative cooling | Litcius