TY - JOUR
T1 - Eco-friendly passive radiative cooling using recycled packaging plastics
AU - Liu, Y.
AU - Liu, X.
AU - Chen, F.
AU - Tian, Y.
AU - Caratenuto, A.
AU - Mu, Y.
AU - Cui, S.
AU - Minus, M. L.
AU - Zheng, Y.
N1 - Generated from Scopus record by KAUST IRTS on 2023-09-23
PY - 2023/9/1
Y1 - 2023/9/1
N2 - Passive daytime radiative cooling, requiring zero external energy consumption, is a promising cooling strategy achieved by simultaneously reflecting solar irradiance and thermally radiating heat into the cold outer space (∼ 3 K) through the atmospheric transparency window. However, current materials for passive radiative cooling face huge challenges, such as complicated fabrication approaches, expensive raw materials, and environmental requirements for practical applications. In line with the urgent need for plastic recycling to curb global environmental pollution, the recycled plastics are used to fabricate a passive radiative cooling material. Herein, the foam-paper composite (FPC) with excellent self-cooling capability is fabricated by a simple crushing-and-mixing procedure using recycled polystyrene (PS) foam and printer paper. The superhydrophobic PS foam particles not only protect the FPC from water damage for field applications but also reinforce its solar reflectivity via their porous structure. The cellulose fibers in printer paper can efficiently emit infrared thermal radiation into the cold outer space and bond dispersed PS foam particles together, further increasing its mechanical strength. The combination of highly diffusely reflective PS foam particles and fiber-based printer paper results in a reflectivity of 96% in the solar spectrum, a sub-ambient cooling performance of 8.4 °C, and a maximum radiative cooling power of 90 W/m2 during a 24-h cycle. Meanwhile, the FPC with high humidity can maintain its high solar reflectivity, which promotes its application in humid subtropical areas. Furthermore, the low material cost and ease of fabrication will provide a path for effective daytime radiative cooling, especially in less developed areas.
AB - Passive daytime radiative cooling, requiring zero external energy consumption, is a promising cooling strategy achieved by simultaneously reflecting solar irradiance and thermally radiating heat into the cold outer space (∼ 3 K) through the atmospheric transparency window. However, current materials for passive radiative cooling face huge challenges, such as complicated fabrication approaches, expensive raw materials, and environmental requirements for practical applications. In line with the urgent need for plastic recycling to curb global environmental pollution, the recycled plastics are used to fabricate a passive radiative cooling material. Herein, the foam-paper composite (FPC) with excellent self-cooling capability is fabricated by a simple crushing-and-mixing procedure using recycled polystyrene (PS) foam and printer paper. The superhydrophobic PS foam particles not only protect the FPC from water damage for field applications but also reinforce its solar reflectivity via their porous structure. The cellulose fibers in printer paper can efficiently emit infrared thermal radiation into the cold outer space and bond dispersed PS foam particles together, further increasing its mechanical strength. The combination of highly diffusely reflective PS foam particles and fiber-based printer paper results in a reflectivity of 96% in the solar spectrum, a sub-ambient cooling performance of 8.4 °C, and a maximum radiative cooling power of 90 W/m2 during a 24-h cycle. Meanwhile, the FPC with high humidity can maintain its high solar reflectivity, which promotes its application in humid subtropical areas. Furthermore, the low material cost and ease of fabrication will provide a path for effective daytime radiative cooling, especially in less developed areas.
UR - https://linkinghub.elsevier.com/retrieve/pii/S2589234723001343
UR - http://www.scopus.com/inward/record.url?scp=85166649989&partnerID=8YFLogxK
U2 - 10.1016/j.mtsust.2023.100448
DO - 10.1016/j.mtsust.2023.100448
M3 - Article
SN - 2589-2347
VL - 23
JO - Materials Today Sustainability
JF - Materials Today Sustainability
ER -