624:- In a building designed to optimize direct radiation cooling, the building roof acts as a heat sink to absorb the daily internal loads. The roof acts as the best heat sink because it is the greatest surface exposed to the night sky. Radiate heat transfer with the night sky will remove heat from the building roof, thus cooling the building structure. Roof ponds are an example of this strategy. The roof pond design became popular with the development of the Sky thermal system designed by Harold Hay in 1977. There are various designs and configurations for the roof pond system but the concept is the same for all designs. The roof uses water, either plastic bags filled with water or an open pond, as the heat sink while a system of movable insulation panels regulate the mode of heating or cooling. During daytime in the summer, the water on the roof is protected from the solar radiation and ambient air temperature by movable insulation, which allows it to serve as a heat sink and absorb the heat generated inside through the ceiling. At night, the panels are retracted to allow nocturnal radiation between the roof pond and the night sky, thus removing the stored heat. In winter, the process is reversed so that the roof pond is allowed to absorb solar radiation during the day and release it during the night into the space below.
370:
554:
455:, thereby simultaneously reducing heat gain from the sun and increasing heat removal through radiation. Radiative cooling thus offers potential for passive cooling for residential and commercial buildings. Traditional building surfaces, such as paint coatings, brick and concrete have high emittances of up to 0.96. They radiate heat into the sky to passively cool buildings at night. If made sufficiently reflective to sunlight, these materials can also achieve radiative cooling during the day.
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630:- A heat transfer fluid removes heat from the building structure through radiate heat transfer with the night sky. A common design for this strategy involves a plenum between the building roof and the radiator surface. Air is drawn into the building through the plenum, cooled from the radiator, and cools the mass of the building structure. During the day, the building mass acts as a heat sink.
297:), the sheet of paper radiates more heat to the face than does the darkened cosmos. The effect is blunted by Earth's surrounding atmosphere, and particularly the water vapor it contains, so the apparent temperature of the sky is far warmer than outer space. The sheet does not block the cold, but instead reflects heat to the face and radiates the heat of the face that it just absorbed.
597:, which consisted of a reflection pool of water built on a bed of highly insulative material surrounded by high walls. The high walls provided protection against convective warming, the insulative material of the pool walls would protect against conductive heating from the ground, the large flat plane of water would then permit evaporative and radiative cooling to take place.
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Other notable radiative cooling strategies include dielectric films on metal mirrors, and polymer or polymer composites on silver or aluminum films. Silvered polymer films with solar reflectances of 0.97 and thermal emittance of 0.96, which remain 11 °C cooler than commercial white paints under
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into space, and can achieve 5 °C sub-ambient cooling under direct sunlight. Later researchers developed paintable porous polymer coatings, whose pores scatter sunlight to give solar reflectance of 0.96-0.99 and thermal emittance of 0.97. In experiments under direct sunlight, the coatings achieve
230:
Convective transport of heat, and evaporative transport of latent heat are both important in removing heat from the surface and distributing it in the atmosphere. Pure radiative transport is more important higher up in the atmosphere. Diurnal and geographical variation further complicate the picture.
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In India, such apparatuses consisted of a shallow ceramic tray with a thin layer of water, placed outdoors with a clear exposure to the night sky. The bottom and sides were insulated with a thick layer of hay. On a clear night the water would lose heat by radiation upwards. Provided the air was calm
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Accordingly, designing and fabricating efficient PDRC with sufficiently high solar reflectance (đÂŻsolar) (λâ~â0.3â2.5âÎŒm) to minimize solar heat gain and simultaneously strong LWIR thermal emittance (Δ¯LWIR) to maximize radiative heat loss is highly desirable. When the incoming radiative heat from
520:
dictates that at higher temperatures the radiative emission peak shifts to lower wavelengths (higher frequencies), influencing material selection as a function of operating temperature. In addition to effective radiative cooling, radiative thermal protection systems should provide damage tolerance
346:
stars are no longer generating energy by fusion or gravitational contraction, and have no solar wind. So the only way their temperature changes is by radiative cooling. This makes their temperature as a function of age very predictable, so by observing the temperature, astronomers can deduce the
208:
Infrared radiation can pass through dry, clear air in the wavelength range of 8â13 ÎŒm. Materials that can absorb energy and radiate it in those wavelengths exhibit a strong cooling effect. Materials that can also reflect 95% or more of sunlight in the 200 nanometres to 2.5 ÎŒm range can
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An alternative, third geoengineering approach would be enhanced cooling by thermal radiation from the Earth's surface into space." "With 100âŻW m as a demonstrated passive cooling effect, a surface coverage of 0.3% would then be needed, or 1% of Earth's land mass surface. If half of it would be
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The most common radiative coolers found on buildings are white cool-roof paint coatings, which have solar reflectances of up to 0.94, and thermal emittances of up to 0.96. The solar reflectance of the paints arises from optical scattering by the dielectric pigments embedded in the polymer paint
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particles embedded in polymers that are translucent in the solar wavelengths and emissive in the infrared. In 2017, an example of this design with resonant polar silica microspheres randomly embedded in a polymeric matrix, was reported. The material is translucent to sunlight and has infrared
533:
uses radiative cooling to reach its operation temperature of about 50 K. To do this, its large reflective sunshield blocks radiation from the Sun, Earth, and Moon. The telescope structure, kept permanently in shadow by the sunshield, then cools by radiation.
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Passive daytime radiative cooling (PDRC) dissipates terrestrial heat to the extremely cold outer space without using any energy input or producing pollution. It has the potential to simultaneously alleviate the two major problems of energy crisis and global
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resin, while the thermal emittance arises from the polymer resin. However, because typical white pigments like titanium dioxide and zinc oxide absorb ultraviolet radiation, the solar reflectances of paints based on such pigments do not exceed 0.95.
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of 0.93 in the infrared atmospheric transmission window. When backed with silver coating, the material achieved a midday radiative cooling power of 93 W/m under direct sunshine along with high-throughput, economical roll-to-roll manufacturing.
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By covering the Earth with a small fraction of thermally emitting materials, the heat flow away from the Earth can be increased, and the net radiative flux can be reduced to zero (or even made negative), thus stabilizing (or cooling) the
254:
in the atmosphere. Thus the tropics radiate less to space than they would if there were no circulation, and the poles radiate more; however in absolute terms the tropics radiate more energy to space.
1772:...terrestrial radiative cooling has emerged as a promising solution for mitigating urban heat islands and for potentially fighting against global warming if it can be implemented at a large scale.
379:(PDRC) (also passive radiative cooling, daytime passive radiative cooling, radiative sky cooling, photonic radiative cooling, and terrestrial radiative cooling) is the use of unpowered, reflective/
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to estimate the age of the Earth (although his estimate ignored the substantial heat released by radioisotope decay, not known at the time, and the effects of convection in the mantle).
373:
PDRC can lower temperatures with zero energy consumption or pollution by radiating heat into outer space. Widespread application has been proposed as a solution to global warming.
2367:
Raman, Aaswath P.; Anoma, Marc Abou; Zhu, Linxiao; Rephaeli, Eden; Fan, Shanhui (November 2014). "Passive radiative cooling below ambient air temperature under direct sunlight".
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installed in urban, built areas which cover roughly 3% of the Earth's land mass, a 17% coverage would be needed there, with the remainder being installed in rural areas.
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331:
2250:
640:: it will then absorb light at some wavelengths, but radiate the energy away again at other, selected wavelengths. By selectively radiating heat in the
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for several seconds, to that after placing a sheet of paper between the face and the sky. Since outer space radiates at about a temperature of 3
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Passive radiative cooling utilizes atmospheric transparency window (8â13 ÎŒm) to discharge heat into outer space and inhibits solar absorption.
831:
Shao, Gaofeng; et al. (2019). "Improved oxidation resistance of high emissivity coatings on fibrous ceramic for reusable space systems".
462:
In 2014, researchers developed the first daytime radiative cooler using a multi-layer thermal photonic structure that selectively emits
2445:
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1577:"The relative role of solar reflectance and thermal emittance for passive daytime radiative cooling technologies applied to rooftops"
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1552:
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Before the invention of artificial refrigeration technology, ice making by nocturnal cooling was common in both India and Iran.
96:
2128:
Gentle, A. R.; Smith, G. B. (2010-02-10). "Radiative Heat
Pumping from the Earth Using Surface Phonon Resonant Nanoparticles".
1554:"Optically Modulated Passive Broadband Daytime Radiative Cooling Materials Can Cool Cities in Summer and Heat Cities in Winter"
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Sharifi, Ayyoob; Yamagata, Yoshiki (December 2015). "Roof ponds as passive heating and cooling systems: A systematic review".
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68:
2316:
1622:
Liang, Jun; Wu, Jiawei; Guo, Jun; Li, Huagen; Zhou, Xianjun; Liang, Sheng; Qiu, Cheng-Wei; Tao, Guangming (September 2022).
1513:
Benmoussa, Youssef; Ezziani, Maria; Djire, All-Fousseni; Amine, Zaynab; Khaldoun, Asmae; Limami, Houssame (September 2022).
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is generally used for local processes, though the same principles apply to cooling over geological time, which was first
75:
49:
242:, mostly because of geometrical factors. The atmospheric and oceanic circulation redistributes some of this energy as
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the Sun is balanced by the outgoing radiative heat emission, the temperature of the Earth can reach its steady state.
376:
362:
192:
115:
20:
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444:, or the whiter a roof, the higher its solar reflectance and heat emittance, which can reduce energy use and costs.
82:
2268:"XXII. The process of making ice in the East Indies. By Sir Robert Barker, F. R. S. in a letter to Dr. Brocklesby"
238:
is driven by the difference in absorbed solar radiation per square meter, as the sun heats the Earth more in the
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53:
803:
64:
1468:"Review on passive daytime radiative cooling: Fundamentals, recent researches, challenges and opportunities"
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and may incorporate self-healing functions through the formation of a viscous glass at high temperatures.
644:, a range of frequencies in which the atmosphere is unusually transparent, an object can effectively use
1865:
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made daytime radiative cooling possible. It has since been proposed as a strategy to mitigate local and
757:
Li, Wei; Fan, Shanhui (1 November 2019). "Radiative
Cooling: Harvesting the Coldness of the Universe".
530:
1514:
277:
The effect can be experienced by comparing skin temperature from looking straight up into a cloudless
1728:"Terrestrial radiative cooling: Using the cold universe as a renewable and sustainable energy source"
1515:"Simulation of an energy-efficient cool roof with cellulose-based daytime radiative cooling material"
153:
1827:
1334:
937:
512:) is applied on a thermally insulating ceramic substrate. In such heat shields high levels of total
2170:
1281:"Radiative cooling through the atmospheric window: A third, less intrusive geoengineering approach"
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493:
412:
218:
188:
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Fan, Shanhui; Li, Wei (March 2022). "Photonics and thermodynamics concepts in radiative cooling".
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176:
42:
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Radiative cooling is one of the few ways an object in space can give off energy. In particular,
1966:"Hierarchically porous polymer coatings for highly efficient passive daytime radiative cooling"
516:, typically in the range 0.8 - 0.9, need to be maintained across a range of high temperatures.
89:
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227:) radiation which balances the absorption of short-wave (visible light) energy from the sun.
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1374:"Global Radiative Sky Cooling Potential Adjusted for Population Density and Cooling Demand"
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from Earth's surface, or from the skin of a human observer. The effect is well-known among
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Radiative cooling has been applied in various contexts throughout human history, including
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1624:"Radiative cooling for passive thermal management towards sustainable carbon neutrality"
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Raman, Aaswath P.; Anoma, Marc Abou; Zhu, Linxiao; Raphaeli, Eden; Fan, Shanhui (2014).
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the mid-summer sun, were reported in 2015. Researchers explored designs with dielectric
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1183:"Passive daytime radiative cooling: Fundamentals, material designs, and applications"
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This article is about the natural process. For the renewable cooling method, see
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Ahmed, Salman; Li, Zhenpeng; Javed, Muhammad
Shahzad; Ma, Tao (September 2021).
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The three basic types of radiant cooling are direct, indirect, and fluorescent:
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977:"Passive Radiative Cooling Below Ambient air Temperature under Direct Sunlight"
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1789:"A review on the integration of radiative cooling and solar energy harvesting"
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1335:"Heat-shedding with photonic structures: radiative cooling and its potential"
1228:"A structural polymer for highly efficient all-day passive radiative cooling"
938:"Heat-shedding with photonic structures: radiative cooling and its potential"
778:
594:
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PDRCs can aid systems that are more efficient at lower temperatures, such as
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It has been proposed as a method of reducing temperature increases caused by
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1122:"On the theory of white dwarf stars. I. The energy sources of white dwarfs"
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Chen, Meijie; Pang, Dan; Chen, Xingyu; Yan, Hongjie; Yang, Yuan (2022).
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of 8â13 ÎŒm to radiate heat into outer space and impede solar absorption.
2447:"Fluorescent cooling of objects exposed to sunlight â The ruby example"
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1350:
1226:
Wang, Tong; Wu, Yi; Shi, Lan; Hu, Xinhua; Chen, Min; Wu, Limin (2021).
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The Earth-atmosphere system is radiatively cooled, emitting long-wave (
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2149:
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1466:
Bijarniya, Jay
Prakash; Sarkar, Jahar; Maiti, Pralay (November 2020).
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and not too far above freezing, heat gain from the surrounding air by
2034:
1777:
1726:
Yin, Xiaobo; Yang, Ronggui; Tan, Gang; Fan, Shanhui (November 2020).
1719:
1615:
1568:
1545:
1506:
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Anand, Jyothis; Sailor, David J.; Baniassadi, Amir (February 2021).
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Radiative cooling is commonly experienced on cloudless nights, when
31:
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aircraft. In such heat shields a high emissivity material, such as
2444:
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surfaces to lower the temperature of a building or other object.
308:
to form on surfaces exposed to the clear night sky, even when the
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6 °C sub-ambient temperatures and cooling powers of 96 W/m.
440:
Different roof materials absorb more or less heat. A higher roof
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as a heat sink, and cool to well below ambient air temperature.
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137:
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Aili, Ablimit; Yin, Xiaobo; Yang, Ronggui (October 2021).
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partly via the mean flow and partly via eddies, known as
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2240:"Lesson 1: History Of Refrigeration, Version 1 ME"
1963:
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2050:"Réfrigération radiative. Effet de serre inverse"
1413:Chen, Jianheng; Lu, Lin; Gong, Quan (June 2021).
1126:Monthly Notices of the Royal Astronomical Society
496:that facilitate radiative cooling may be used in
2484:
1890:"Find rated products â Cool Roof Rating Council"
198:
175:for spacecraft, and in architecture. In 2014, a
2331:
2189:
1278:
1180:
423:Passive radiative cooling technologies use the
300:The same radiative cooling mechanism can cause
1786:
613:intensity, from clouds, atmosphere and surface
1825:
1725:
1332:
935:
590:was low enough to allow the water to freeze.
524:
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1639:
1397:
1251:
1198:
1145:
1096:
1055:
912:
886:
844:
593:In Iran, this involved making large flat
451:combine high solar reflectance with high
209:exhibit cooling even in direct sunlight.
116:Learn how and when to remove this message
2247:Indian Institute of Technology Kharagpur
1472:Renewable and Sustainable Energy Reviews
666:, used for thermal control of spacecraft
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435:
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368:
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152:spontaneously and continuously emits
136:is the process by which a body loses
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880:
830:
798:
796:
316:Kelvin's estimate of the Earth's age
54:adding citations to reliable sources
25:
1866:"Emissivity Coefficients Materials"
1078:
498:reusable thermal protection systems
234:The large-scale circulation of the
13:
968:
929:
464:long wavelength infrared radiation
389:by reducing the energy needed for
14:
2509:
877:
793:
377:Passive daytime radiative cooling
363:Passive daytime radiative cooling
355:
193:passive daytime radiative cooling
21:passive daytime radiative cooling
16:Loss of heat by thermal radiation
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1832:Journal of Materials Chemistry C
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2183:
2164:
2121:
2072:
2041:
2006:
1957:
1906:
1882:
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1154:
1113:
559:Radiative cooling energy budget
488:
431:
350:
41:needs additional citations for
2354:10.1016/j.apenergy.2015.09.061
1581:Sustainable Cities and Society
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1072:
1023:
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312:does not fall below freezing.
1:
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1057:10.1016/j.joule.2019.07.010
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642:infrared atmospheric window
634:Fluorescent radiant cooling
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525:James Webb Space Telescope
360:
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18:
1601:10.1016/j.scs.2020.102612
759:Optics and Photonics News
685:Terrestrial albedo effect
609:Earth's longwave thermal
500:(RTPS) in spacecraft and
413:thermoelectric generators
258:Nocturnal surface cooling
154:electromagnetic radiation
808:Field Study of the World
779:10.1364/OPN.30.11.000032
636:- An object can be made
628:Indirect radiant cooling
600:
494:High emissivity coatings
395:urban heat island effect
189:greenhouse gas emissions
2307:Givoni, Baruch (1994).
2217:10.1126/science.aai7899
1991:10.1126/science.aat9513
1793:Materials Today: Energy
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664:Optical solar reflector
177:scientific breakthrough
2285:10.1098/rstl.1775.0023
2097:10.1002/advs.201500119
1162:"Cooling white dwarfs"
905:10.1002/advs.201500360
622:Direct radiant cooling
614:
445:
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181:photonic metamaterials
2498:Atmospheric radiation
1399:10.3390/atmos12111379
1232:Nature Communications
608:
506:molybdenum disilicide
439:
422:
397:, and lowering human
372:
320:Further information:
219:Earth's energy budget
217:Further information:
213:Earth's energy budget
680:StefanâBoltzmann law
571:Ice Pool beside the
405:photovoltaic systems
50:improve this article
2463:2016SEMSC.157..312B
2389:10.1038/nature13883
2381:2014Natur.515..540R
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2208:2017Sci...355.1062Z
2202:(6329): 1062â1066.
2142:2010NanoL..10..373G
2027:1981JAP....52.4205G
1982:2018Sci...362..315M
1935:10.1038/nature13883
1927:2014Natur.515..540R
1805:2021MTEne..2100776A
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1691:2019Joule...3.2057M
1641:10.1093/nsr/nwac208
1593:2021SusCS..6502612A
1484:2020RSERv.13310263B
1431:2021ECM...23714132C
1390:2021Atmos..12.1379A
1297:2018Ene...152...27Z
1138:1952MNRAS.112..583M
1120:Mestel, L. (1952).
1048:2019Joule...3.2057M
1001:10.1038/nature13883
993:2014Natur.515..540R
855:2019Corro.146..233S
771:2019OptPN..30...32L
728:2022NaPho..16..182F
695:Urban thermal plume
310:ambient temperature
272:amateur astronomers
65:"Radiative cooling"
2432:large.stanford.edu
1844:10.1039/D2TC00318J
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954:10.1039/D2TC00318J
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2278:: 252â257. 1997.
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833:Corrosion Science
690:Urban heat island
675:Radiative forcing
399:body temperatures
347:age of the star.
328:radiative cooling
266:is radiated into
148:describes, every
142:thermal radiation
134:radiative cooling
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295:room temperature
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2130:Nano Letters
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518:Planck's law
492:
489:Heat shields
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432:Architecture
384:
351:Applications
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229:
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173:heat shields
158:
146:Planck's law
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48:Please help
43:verification
40:
2457:: 312â317.
2340:: 336â357.
839:: 233â246.
659:Heat shield
646:outer space
638:fluorescent
344:white dwarf
268:outer space
248:latent heat
2487:Categories
1899:2019-02-23
1875:2019-02-23
1799:: 100776.
1587:: 102612.
1478:: 110263.
1425:: 114132.
1378:Atmosphere
846:1902.03943
814:2019-04-28
765:(11): 32.
701:References
588:convection
542:See also:
514:emissivity
502:hypersonic
482:emissivity
449:Cool roofs
187:caused by
161:ice making
76:newspapers
2397:1476-4687
1852:249695930
1768:226308213
1709:201590290
1609:229476136
1539:252136357
1500:224874019
1447:234839652
1359:249695930
1313:116318678
1209:240331557
1066:201590290
962:249695930
871:118927116
787:209957921
744:246668570
611:radiation
595:ice pools
338:Astronomy
326:The term
306:black ice
279:night sky
204:Mechanism
191:known as
2405:25428501
2226:28183998
2158:20055479
2115:27980975
2000:30262632
1943:25428501
1760:33184205
1660:36684522
1262:33446648
1214:warming.
1107:31892746
1009:25428501
923:27812478
653:See also
544:YakhchÄl
252:cyclones
225:infrared
2459:Bibcode
2413:4382732
2377:Bibcode
2342:Bibcode
2204:Bibcode
2196:Science
2138:Bibcode
2106:5115392
2023:Bibcode
1978:Bibcode
1970:Science
1951:4382732
1923:Bibcode
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1651:9843130
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1427:Bibcode
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1293:Bibcode
1253:7809060
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1044:Bibcode
1017:4382732
989:Bibcode
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851:Bibcode
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724:Bibcode
240:Tropics
90:scholar
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2369:Nature
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1285:Energy
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981:Nature
960:
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442:albedo
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2290:JSTOR
2254:(PDF)
2243:(PDF)
1947:S2CID
1848:S2CID
1764:S2CID
1705:S2CID
1679:Joule
1605:S2CID
1535:S2CID
1496:S2CID
1443:S2CID
1355:S2CID
1309:S2CID
1205:S2CID
1165:(PDF)
1062:S2CID
1036:Joule
1013:S2CID
958:S2CID
867:S2CID
841:arXiv
783:S2CID
740:S2CID
601:Types
508:(MoSi
302:frost
165:India
144:. As
97:JSTOR
83:books
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2222:PMID
2154:PMID
2111:PMID
1996:PMID
1939:PMID
1756:PMID
1656:PMID
1258:PMID
1103:PMID
1005:PMID
919:PMID
529:The
264:heat
246:and
169:Iran
167:and
138:heat
69:news
2467:doi
2455:157
2385:doi
2373:515
2350:doi
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2280:doi
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1986:doi
1974:362
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1919:515
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1736:370
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1527:doi
1488:doi
1476:133
1435:doi
1423:237
1394:doi
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