Ultrahigh Passive Cooling Power in Hydrogel with Rationally Designed Optofluidic Properties

Jipeng Fei; Di Han; Xuan Zhang; Ke Li; Nicolas Lavielle; Kai Zhou; Xingli Wang; Jun Yan Tan; Jianwei Zhong; Man Pun Wan; Elyes Nefzaoui; Tarik Bourouina; Shuzhou Li; Bing Feng Ng; Lili Cai; Hong Li

doi:10.1021/acs.nanolett.3c03694

Ultrahigh Passive Cooling Power in Hydrogel with Rationally Designed Optofluidic Properties

Jipeng Fei
, Di Han
, Xuan Zhang
, Ke Li
, Nicolas Lavielle
, Kai Zhou
, Xingli Wang
, Jun Yan Tan
, Jianwei Zhong
, Man Pun Wan
, Elyes Nefzaoui
, Tarik Bourouina
, Shuzhou Li
, Bing Feng Ng
, Lili Cai
, Hong Li^*

^*此作品的通讯作者

机械与车辆学院

Nanyang Technological University
Agency for Science, Technology and Research, Singapore
Universite Paris-Est
University of Illinois at Urbana-Champaign
Research Techno Plaza Singapore
Singapore University of Technology and Design

科研成果: 期刊稿件 › 文章 › 同行评审

26 引用（Scopus）

摘要

The cooling power of a radiative cooler is more than halved in the tropics, e.g., Singapore, because of its harsh weather conditions including high humidity (84% on average), strong downward atmospheric radiation (∼40% higher than elsewhere), abundant rainfall, and intense solar radiation (up to 1200 W/m² with ∼58% higher UV irradiation). So far, there has been no report of daytime radiative cooling that well achieves effective subambient cooling. Herein, through integrated passive cooling strategies in a hydrogel with desirable optofluidic properties, we demonstrate stable subambient (4-8 °C) cooling even under the strongest solar radiation in Singapore. The integrated passive cooler achieves an ultrahigh cooling power of ∼350 W/m², 6-10 times higher than a radiative cooler in a tropical climate. An in situ study of radiative cooling with various hydration levels and ambient humidity is conducted to understand the interaction between radiation and evaporative cooling. This work provides insights for the design of an integrated cooler for various climates.

源语言	英语
页（从-至）	623-631
页数	9
期刊	Nano Letters
卷	24
期	2
DOI	https://doi.org/10.1021/acs.nanolett.3c03694
出版状态	已出版 - 17 1月 2024

联合国可持续发展目标

此成果有助于实现下列可持续发展目标：

可持续发展目标 13 气候行动

访问文件

10.1021/acs.nanolett.3c03694

其它文件与链接

链接到 Scopus 的出版物

引用此

@article{25872d4a6b7440eab4157120a6f12209,

title = "Ultrahigh Passive Cooling Power in Hydrogel with Rationally Designed Optofluidic Properties",

abstract = "The cooling power of a radiative cooler is more than halved in the tropics, e.g., Singapore, because of its harsh weather conditions including high humidity (84\% on average), strong downward atmospheric radiation (∼40\% higher than elsewhere), abundant rainfall, and intense solar radiation (up to 1200 W/m2 with ∼58\% higher UV irradiation). So far, there has been no report of daytime radiative cooling that well achieves effective subambient cooling. Herein, through integrated passive cooling strategies in a hydrogel with desirable optofluidic properties, we demonstrate stable subambient (4-8 °C) cooling even under the strongest solar radiation in Singapore. The integrated passive cooler achieves an ultrahigh cooling power of ∼350 W/m2, 6-10 times higher than a radiative cooler in a tropical climate. An in situ study of radiative cooling with various hydration levels and ambient humidity is conducted to understand the interaction between radiation and evaporative cooling. This work provides insights for the design of an integrated cooler for various climates.",

keywords = "hydrogel, integrated cooling structure, optofluidic design, passive cooling, radiative cooling",

author = "Jipeng Fei and Di Han and Xuan Zhang and Ke Li and Nicolas Lavielle and Kai Zhou and Xingli Wang and Tan, \{Jun Yan\} and Jianwei Zhong and Wan, \{Man Pun\} and Elyes Nefzaoui and Tarik Bourouina and Shuzhou Li and Ng, \{Bing Feng\} and Lili Cai and Hong Li",

note = "Publisher Copyright: {\textcopyright} 2023 American Chemical Society.",

year = "2024",

month = jan,

day = "17",

doi = "10.1021/acs.nanolett.3c03694",

language = "English",

volume = "24",

pages = "623--631",

journal = "Nano Letters",

issn = "1530-6984",

publisher = "American Chemical Society",

number = "2",

}

TY - JOUR

T1 - Ultrahigh Passive Cooling Power in Hydrogel with Rationally Designed Optofluidic Properties

AU - Fei, Jipeng

AU - Han, Di

AU - Zhang, Xuan

AU - Li, Ke

AU - Lavielle, Nicolas

AU - Zhou, Kai

AU - Wang, Xingli

AU - Tan, Jun Yan

AU - Zhong, Jianwei

AU - Wan, Man Pun

AU - Nefzaoui, Elyes

AU - Bourouina, Tarik

AU - Li, Shuzhou

AU - Ng, Bing Feng

AU - Cai, Lili

AU - Li, Hong

PY - 2024/1/17

Y1 - 2024/1/17

N2 - The cooling power of a radiative cooler is more than halved in the tropics, e.g., Singapore, because of its harsh weather conditions including high humidity (84% on average), strong downward atmospheric radiation (∼40% higher than elsewhere), abundant rainfall, and intense solar radiation (up to 1200 W/m2 with ∼58% higher UV irradiation). So far, there has been no report of daytime radiative cooling that well achieves effective subambient cooling. Herein, through integrated passive cooling strategies in a hydrogel with desirable optofluidic properties, we demonstrate stable subambient (4-8 °C) cooling even under the strongest solar radiation in Singapore. The integrated passive cooler achieves an ultrahigh cooling power of ∼350 W/m2, 6-10 times higher than a radiative cooler in a tropical climate. An in situ study of radiative cooling with various hydration levels and ambient humidity is conducted to understand the interaction between radiation and evaporative cooling. This work provides insights for the design of an integrated cooler for various climates.

AB - The cooling power of a radiative cooler is more than halved in the tropics, e.g., Singapore, because of its harsh weather conditions including high humidity (84% on average), strong downward atmospheric radiation (∼40% higher than elsewhere), abundant rainfall, and intense solar radiation (up to 1200 W/m2 with ∼58% higher UV irradiation). So far, there has been no report of daytime radiative cooling that well achieves effective subambient cooling. Herein, through integrated passive cooling strategies in a hydrogel with desirable optofluidic properties, we demonstrate stable subambient (4-8 °C) cooling even under the strongest solar radiation in Singapore. The integrated passive cooler achieves an ultrahigh cooling power of ∼350 W/m2, 6-10 times higher than a radiative cooler in a tropical climate. An in situ study of radiative cooling with various hydration levels and ambient humidity is conducted to understand the interaction between radiation and evaporative cooling. This work provides insights for the design of an integrated cooler for various climates.

KW - hydrogel

KW - integrated cooling structure

KW - optofluidic design

KW - passive cooling

KW - radiative cooling

UR - https://www.scopus.com/pages/publications/85180109197

U2 - 10.1021/acs.nanolett.3c03694

DO - 10.1021/acs.nanolett.3c03694

M3 - Article

C2 - 38048272

AN - SCOPUS:85180109197

SN - 1530-6984

VL - 24

SP - 623

EP - 631

JO - Nano Letters

JF - Nano Letters

IS - 2

ER -

Ultrahigh Passive Cooling Power in Hydrogel with Rationally Designed Optofluidic Properties

摘要

联合国可持续发展目标

访问文件

其它文件与链接

指纹

引用此