Litcius/Paper detail

Radiative Thermal Management in Face Masks with a Micro/Nanofibrous Filter

Yuanqiang Xu, Xiaomin Zhang, Tienan Zhao, Ying Li, Yu Zhang, Hui Huang, Yongchun Zeng

2024Nano Letters18 citationsDOI

Abstract

Micro/nanofiber-based face masks are recommended as personal protective equipment (PPE) against particulate matter (PM), especially PM 0.3 . Ensuring thermal comfort in daily use face masks is essential in many situations. Here, radiative thermal management is introduced into face masks to elevate the user comfort. An interlayered poly(lactic acid) (PLA) micro/nanofibrous filter effectively captures PM 0.3 (99.69%) with minimal pressure drop (49 Pa). Thermal regulation is accomplished by controlling the mid-infrared (MIR) emissivity of the face mask’s outer surface. Cooling face masks feature cotton nonwovens with high MIR emissivity (90.7%) for heat dissipation, while warming face masks utilize perforated Al/PE films with minimal MIR emissivity (10.7%) for warmth retention. Skin temperature measurements indicate that the skin covered by the cooling face mask could be 1.1 °C lower than that covered by the 3M face mask, while the skin covered by the warming face mask could be 1.3 °C higher than that covered by the 3M face mask.

Topics & Concepts

EmissivityMaterials scienceFace masksThermal management of electronic devices and systemsThermal radiationThermal infraredRadiant heatThermal comfortRadiative coolingFace (sociological concept)Radiative transferThermalOpticsEnvironmental scienceComposite materialOptoelectronicsInfraredMechanical engineeringMeteorologyCoronavirus disease 2019 (COVID-19)PhysicsEngineeringThermodynamicsMedicineInfectious disease (medical specialty)SociologySocial sciencePathologyDiseaseThermal Radiation and Cooling TechnologiesBuilding Energy and Comfort OptimizationInfection Control and Ventilation
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