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Template-Thermally Induced Phase Separation-Assisted Microporous Regulation in Poly(lactic acid) Aerogel for Sustainable Radiative Cooling

Han Jia, Mulan Mu, Yangzhe Hou, Yamin Pan, Chuntai Liu, Changyu Shen, Xianhu Liu

2025Biomacromolecules16 citationsDOI

Abstract

Herein, an eco-friendly and degradable poly(lactic acid) aerogel was prepared by combining a poly(ethylene glycol) template material with thermally induced phase separation. Due to the tailored pore size introduced by the template material, the aerogel exhibits high solar reflectance (92.0%), excellent thermal emittance (90.5%), low thermal conductivity (52.0 mW m –1 K –1 ), and high compressive strength (0.15 MPa). Cooling tests demonstrate that the aerogel can achieve temperature drops of 3.7 °C during the day and of 6.2 °C at night. Furthermore, simulations of building cooling energy systems reveal that the aerogel can reduce energy consumption by 2.2 to 10.2 MJ m –2 per year in various cities, achieving energy savings ranging from 8.2 to 24.3%. Meanwhile, the aerogel cooler demonstrates excellent self-cleaning performance (WCA = 149.1°) and cyclic compression performance. This research will promote the field of passive radiative cooling toward a greener and more sustainable direction.

Topics & Concepts

AerogelMicroporous materialLactic acidPhase (matter)Chemical engineeringChemistryRadiative coolingMaterials scienceOrganic chemistryNanotechnologyThermodynamicsBacteriaPhysicsEngineeringBiologyGeneticsThermal Radiation and Cooling TechnologiesUrban Heat Island MitigationBuilding Energy and Comfort Optimization
Template-Thermally Induced Phase Separation-Assisted Microporous Regulation in Poly(lactic acid) Aerogel for Sustainable Radiative Cooling | Litcius