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Eco-Friendly Skin-Wrinkle-Inspired Micro-Nano Structured Cellulose Composite Fibers for Highly Efficient Daytime Radiative Cooling

Qihua Li, Jianfeng Li, Chen Zeng, Jing Song, Yuchen Jiang, Hai-ning Yu, Yu Fang, Shufeng Hu, Youwei Zhang, Weiqing Kong, Meifang Zhu

2025ACS Nano15 citationsDOI

Abstract

Passive radiative cooling fabrics offer a sustainable pathway to reduce energy consumption in thermal management, yet their reliance on petroleum-derived materials and complex coating processes compromises both environmental compatibility and wearability. To address these challenges, we propose a bioinspired, coating-free strategy by designing regenerated cellulose/SiO 2 nanoparticle fibers (RCSF) via wet-spinning. Mimicking the micro-nano structure of the human skin surface (protrusion height ≈ 2 μm), the RCSF achieves simultaneous high solar reflectivity (93.7% at 0.4–1 μm) and infrared emissivity (0.98 at 8–13 μm) through intrinsic material properties rather than external coatings. The hierarchical porous structure enhances the specific surface area while maintaining air permeability (75% improvement vs pristine cellulose fabrics) and moisture-wicking performance. Under 800 W m –2 solar irradiation, RCSF exhibits a net cooling power of 100.1 W m –2, translating to a 5 °C temperature reduction in summer environments compared with regenerated cellulose fibers (RCF). Crucially, this one-step fabrication method eliminates toxic paints and energy-intensive post-treatments, offering a cost-effective alternative to conventional coated fabrics. By integrating renewable cellulose with skin-wrinkle-inspired structural design, our work establishes a paradigm for eco-efficient radiative cooling materials that balance optical performance, wearer comfort, and scalable manufacturing.

Topics & Concepts

Materials scienceEmissivityCoatingFabricationRadiative coolingComposite materialCelluloseComposite numberThermalRadiative transferRenewable energyOptoelectronicsCellulose fiberCladding (metalworking)Optical fiberInfraredPassive coolingPorositySolar energyAir permeability specific surfaceThermal conductivityScatteringLow emissivityNanoparticleNanotechnologyThermal radiationWork (physics)Process engineeringPorous mediumPhotocatalysisOpticsThermal energy storageConcentrated solar powerThermal Radiation and Cooling TechnologiesUrban Heat Island MitigationBuilding Energy and Comfort Optimization
Eco-Friendly Skin-Wrinkle-Inspired Micro-Nano Structured Cellulose Composite Fibers for Highly Efficient Daytime Radiative Cooling | Litcius