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Significantly enhanced sub-ambient passive cooling enabled by evaporation, radiation, and insulation

Zhengmao Lu, Arny Leroy, Lenan Zhang, Jatin J. Patil, Evelyn N. Wang, Jeffrey C. Grossman

2022Cell Reports Physical Science35 citationsDOIOpen Access PDF

Abstract

Passive cooling relying on evaporation and radiation, while offering great energy-saving opportunities, faces challenges with low ambient cooling powers, environmental heating, high water usage, and climate condition constraints. To overcome these shortcomings, here, we present insulated cooling with evaporation and radiation (ICER), which utilizes a solar-reflecting layer; an infrared-emitting evaporative layer; and an infrared-transparent, solar-reflecting, and vapor-permeable insulation layer. One major advantage of ICER is that it synergistically combines thermal insulation, evaporative cooling, and radiative cooling. Consequently, it consistently achieves below-wet-bulb temperatures with much less water consumption than pure evaporation while reaching 9.3°C below the ambient temperature under direct sunlight. With unfavorable climate conditions, ICER delivers 96 W/m2 daytime cooling power at the ambient temperature and shows a 300% enhancement over the state-of-the-art radiative cooler. During the summer months, without electricity, ICER can extend food shelf life by 40% in humid climates and 200% in dry climates with low water-refilling frequencies.

Topics & Concepts

Evaporative coolerRadiative coolingEvaporationEnvironmental sciencePassive coolingThermal insulationAtmospheric sciencesRadiationMaterials scienceInfraredMeteorologyWater vaporNuclear engineeringLayer (electronics)ThermalComposite materialOpticsPhysicsEngineeringThermal Radiation and Cooling TechnologiesUrban Heat Island MitigationBuilding Energy and Comfort Optimization
Significantly enhanced sub-ambient passive cooling enabled by evaporation, radiation, and insulation | Litcius