Metamaterial-Based Radiative Cooling: Towards Energy-Free All-Day Cooling

Metamaterial-Based Radiative Cooling: Towards Energy-Free All-Day Cooling

In the light of the ever increasing dangers of global warming, the efforts to reduce energy consumption by radiative cooling techniques have been designed, but are inefficient under strong sunlight during the daytime. With the advent of metamaterials and their selective control over optical properti...

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Main Authors: Byoungsu Ko, Dasol Lee, Trevon Badloe, Junsuk Rho
Format: Article
Language:English
Published: MDPI AG 2018-12-01
Series:Energies
Subjects:
metamaterial
daytime radiative cooling
infrared atmospheric window
selective reflection
selective emission
Online Access:http://www.mdpi.com/1996-1073/12/1/89
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spelling doaj-8f70a885f72b49a783272be37d1cf81a2020-11-24T21:47:58ZengMDPI AGEnergies1996-10732018-12-011218910.3390/en12010089en12010089Metamaterial-Based Radiative Cooling: Towards Energy-Free All-Day CoolingByoungsu Ko0Dasol Lee1Trevon Badloe2Junsuk Rho3Department of Mechanical Engineering, Myongji University, Yongin 17058, KoreaDepartment of Mechanical Engineering, Pohang University of Science and Technology (POSTECH), Pohang 37673, KoreaDepartment of Mechanical Engineering, Pohang University of Science and Technology (POSTECH), Pohang 37673, KoreaDepartment of Mechanical Engineering, Pohang University of Science and Technology (POSTECH), Pohang 37673, KoreaIn the light of the ever increasing dangers of global warming, the efforts to reduce energy consumption by radiative cooling techniques have been designed, but are inefficient under strong sunlight during the daytime. With the advent of metamaterials and their selective control over optical properties, radiative cooling under direct sunlight is now possible. The key principles of metamaterial-based radiative cooling are: almost perfect reflection in the visible and near-infrared spectrum (0.3–3 µm) and high thermal emission in the infrared atmospheric window region (8–13 µm). Based on these two basic principles, studies have been conducted using various materials and structures to find the most efficient radiative cooling system. In this review, we analyze the materials and structures being used for radiative cooling, and suggest the future perspectives as a substitute in the current cooling industry.http://www.mdpi.com/1996-1073/12/1/89metamaterialdaytime radiative coolinginfrared atmospheric windowselective reflectionselective emission
collection DOAJ
language English
format Article
sources DOAJ
author Byoungsu Ko
Dasol Lee
Trevon Badloe
Junsuk Rho
spellingShingle Byoungsu Ko
Dasol Lee
Trevon Badloe
Junsuk Rho
Metamaterial-Based Radiative Cooling: Towards Energy-Free All-Day Cooling
Energies
metamaterial
daytime radiative cooling
infrared atmospheric window
selective reflection
selective emission
author_facet Byoungsu Ko
Dasol Lee
Trevon Badloe
Junsuk Rho
author_sort Byoungsu Ko
title Metamaterial-Based Radiative Cooling: Towards Energy-Free All-Day Cooling
title_short Metamaterial-Based Radiative Cooling: Towards Energy-Free All-Day Cooling
title_full Metamaterial-Based Radiative Cooling: Towards Energy-Free All-Day Cooling
title_fullStr Metamaterial-Based Radiative Cooling: Towards Energy-Free All-Day Cooling
title_full_unstemmed Metamaterial-Based Radiative Cooling: Towards Energy-Free All-Day Cooling
title_sort metamaterial-based radiative cooling: towards energy-free all-day cooling
publisher MDPI AG
series Energies
issn 1996-1073
publishDate 2018-12-01
description In the light of the ever increasing dangers of global warming, the efforts to reduce energy consumption by radiative cooling techniques have been designed, but are inefficient under strong sunlight during the daytime. With the advent of metamaterials and their selective control over optical properties, radiative cooling under direct sunlight is now possible. The key principles of metamaterial-based radiative cooling are: almost perfect reflection in the visible and near-infrared spectrum (0.3–3 µm) and high thermal emission in the infrared atmospheric window region (8–13 µm). Based on these two basic principles, studies have been conducted using various materials and structures to find the most efficient radiative cooling system. In this review, we analyze the materials and structures being used for radiative cooling, and suggest the future perspectives as a substitute in the current cooling industry.
topic metamaterial
daytime radiative cooling
infrared atmospheric window
selective reflection
selective emission
url http://www.mdpi.com/1996-1073/12/1/89
work_keys_str_mv AT byoungsuko metamaterialbasedradiativecoolingtowardsenergyfreealldaycooling
AT dasollee metamaterialbasedradiativecoolingtowardsenergyfreealldaycooling
AT trevonbadloe metamaterialbasedradiativecoolingtowardsenergyfreealldaycooling
AT junsukrho metamaterialbasedradiativecoolingtowardsenergyfreealldaycooling
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