Bilayer porous polymer for efficient passive building cooling

Chunzao Feng; Peihua Yang; Huidong Liu; Mingran Mao; Yipu Liu; Tong Xue; Jia Fu; Ting Cheng; Xuejiao Hu; Hong Jin Fan; Kang Liu

doi:10.1016/j.nanoen.2021.105971

Bilayer porous polymer for efficient passive building cooling

Chunzao Feng, Peihua Yang, Huidong Liu, Mingran Mao, Yipu Liu, Tong Xue, Jia Fu, Ting Cheng, Xuejiao Hu, Hong Jin Fan^*, Kang Liu

^*Corresponding author for this work

Research output: Contribution to journal › Article › peer-review

188 Citations (Scopus)

Abstract

Passive building cooling without any electricity input are highly desirable in pursuing low energy consumption and environment protection. However, widespread adoption of existing techniques is restrained by the complex system design or low cooling power. Herein, we propose an efficient passive cooling approach with a bilayer porous polymer film, which comprises a hygroscopic hydrogel and a hydrophobic top layer with hierarchical pores. The hydrogel implements evaporative cooling in the daytime and regenerates itself at night. The top layer protects and radiatively cools the hydrogel, which enhances the cooling power during day and helps the hydrogel regeneration at night. With the synergistic effect, the bilayer film attains a remarkable sub-ambient temperature drops of ~7 °C and an effective cooling power of ~150 W·m⁻² under direct sunlight, showing great potential for low-cost, efficient and scalable passive building cooling.

Original language	English
Article number	105971
Journal	Nano Energy
Volume	85
DOIs	https://doi.org/10.1016/j.nanoen.2021.105971
Publication status	Published - Jul 2021
Externally published	Yes

Bibliographical note

Publisher Copyright:
© 2021 Elsevier Ltd

ASJC Scopus Subject Areas

Renewable Energy, Sustainability and the Environment
General Materials Science
Electrical and Electronic Engineering

Keywords

Evaporation
Hierarchically porous‎ ‎polymer
Hydrogel
Passive building cooling
Radiation

UN SDGs

This output contributes to the following UN Sustainable Development Goals (SDGs)

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10.1016/j.nanoen.2021.105971

Cite this

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title = "Bilayer porous polymer for efficient passive building cooling",

abstract = "Passive building cooling without any electricity input are highly desirable in pursuing low energy consumption and environment protection. However, widespread adoption of existing techniques is restrained by the complex system design or low cooling power. Herein, we propose an efficient passive cooling approach with a bilayer porous polymer film, which comprises a hygroscopic hydrogel and a hydrophobic top layer with hierarchical pores. The hydrogel implements evaporative cooling in the daytime and regenerates itself at night. The top layer protects and radiatively cools the hydrogel, which enhances the cooling power during day and helps the hydrogel regeneration at night. With the synergistic effect, the bilayer film attains a remarkable sub-ambient temperature drops of ~7 °C and an effective cooling power of ~150 W·m−2 under direct sunlight, showing great potential for low-cost, efficient and scalable passive building cooling.",

keywords = "Evaporation, Hierarchically porous‎ ‎polymer, Hydrogel, Passive building cooling, Radiation",

author = "Chunzao Feng and Peihua Yang and Huidong Liu and Mingran Mao and Yipu Liu and Tong Xue and Jia Fu and Ting Cheng and Xuejiao Hu and Fan, {Hong Jin} and Kang Liu",

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doi = "10.1016/j.nanoen.2021.105971",

language = "English",

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T1 - Bilayer porous polymer for efficient passive building cooling

AU - Feng, Chunzao

AU - Yang, Peihua

AU - Liu, Huidong

AU - Mao, Mingran

AU - Liu, Yipu

AU - Xue, Tong

AU - Fu, Jia

AU - Cheng, Ting

AU - Hu, Xuejiao

AU - Fan, Hong Jin

AU - Liu, Kang

PY - 2021/7

Y1 - 2021/7

N2 - Passive building cooling without any electricity input are highly desirable in pursuing low energy consumption and environment protection. However, widespread adoption of existing techniques is restrained by the complex system design or low cooling power. Herein, we propose an efficient passive cooling approach with a bilayer porous polymer film, which comprises a hygroscopic hydrogel and a hydrophobic top layer with hierarchical pores. The hydrogel implements evaporative cooling in the daytime and regenerates itself at night. The top layer protects and radiatively cools the hydrogel, which enhances the cooling power during day and helps the hydrogel regeneration at night. With the synergistic effect, the bilayer film attains a remarkable sub-ambient temperature drops of ~7 °C and an effective cooling power of ~150 W·m−2 under direct sunlight, showing great potential for low-cost, efficient and scalable passive building cooling.

AB - Passive building cooling without any electricity input are highly desirable in pursuing low energy consumption and environment protection. However, widespread adoption of existing techniques is restrained by the complex system design or low cooling power. Herein, we propose an efficient passive cooling approach with a bilayer porous polymer film, which comprises a hygroscopic hydrogel and a hydrophobic top layer with hierarchical pores. The hydrogel implements evaporative cooling in the daytime and regenerates itself at night. The top layer protects and radiatively cools the hydrogel, which enhances the cooling power during day and helps the hydrogel regeneration at night. With the synergistic effect, the bilayer film attains a remarkable sub-ambient temperature drops of ~7 °C and an effective cooling power of ~150 W·m−2 under direct sunlight, showing great potential for low-cost, efficient and scalable passive building cooling.

KW - Evaporation

KW - Hierarchically porous‎ ‎polymer

KW - Hydrogel

KW - Passive building cooling

KW - Radiation

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JO - Nano Energy

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Bilayer porous polymer for efficient passive building cooling

Abstract

Bibliographical note

ASJC Scopus Subject Areas

Keywords

UN SDGs

Access to Document

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