Jump to content

Passive daytime radiative cooling

From Wikipedia, the free encyclopedia
(Redirected from Passive radiative cooling)

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.[1]

Passive daytime radiative cooling (PDRC) (also passive radiative cooling, daytime passive radiative cooling, radiative sky cooling, photonic radiative cooling, and terrestrial radiative cooling[2][3][4][5]) is the use of unpowered, reflective/thermally-emissive surfaces to lower the temperature of a building or other object.[6]

It has been proposed as a method of reducing temperature increases caused by greenhouse gases by reducing the energy needed for air conditioning, [7][8] lowering the urban heat island effect,[9][10] and lowering human body temperatures.[11][1][12][13][7]

PDRCs can aid systems that are more efficient at lower temperatures, such as photovoltaic systems,[4][14] dew collection devices, and thermoelectric generators.[15][14]

Some estimates propose that dedicating 1–2% of the Earth's surface area to PDRC would stabilize surface temperatures.[16][3] Regional variations provide different cooling potentials with desert and temperate climates benefiting more than tropical climates, attributed to the effects of humidity and cloud cover.[17][18][19] PDRCs can be included in adaptive systems, switching from cooling to heating to mitigate any potential "overcooling" effects.[20][21] PDRC applications for indoor space cooling is growing with an estimated "market size of ~$27 billion in 2025."[22]

PDRC surfaces are designed to be high in solar reflectance to minimize heat gain and strong in longwave infrared (LWIR) thermal radiation heat transfer matching the atmosphere's infrared window (8–13 μm).[23][2][3] This allows the heat to pass through the atmosphere into space.[6][24]

PDRCs leverage the natural process of radiative cooling, in which the Earth cools by releasing heat to space.[25][26][7] PDRC operates during daytime.[27] On a clear day, solar irradiance can reach 1000 W/m2 with a diffuse component between 50-100 W/m2. The average PDRC has an estimated cooling power of ~100-150 W/m2, proportional to the exposed surface area.[28][29]

PDRC applications are deployed as sky-facing surfaces.[14] Low-cost scalable PDRC materials with potential for mass production include coatings, thin films, metafabrics, aerogels, and biodegradable surfaces.

While typically white, other colors can also work, although generally offering less cooling potential.[30][31]

Research, development, and interest in PDRCs has grown rapidly since the 2010s, attributable to a breakthrough in the use of photonic metamaterials to increase daytime cooling in 2014,[4][32][15][33] along with growing concerns over energy use and global warming.[34][35] PDRC can be contrasted with traditional compression-based cooling systems (e.g., air conditioners) that consume substantial amounts of energy, have a net heating effect (heating the outdoors more than cooling the indoors), require ready access to electric power and often employ coolants that deplete the ozone or have a strong greenhouse effect,[36][37]

Unlike solar radiation management, PDRC increases heat emission beyond simple reflection.[38]

Implementation

[edit]

A 2019 study reported that "widescale adoption of radiative cooling could reduce air temperature near the surface, if not the whole atmosphere."[5] To address global warming, PDRCs must be designed "to ensure that the emission is through the atmospheric transparency window and out to space, rather than just to the atmosphere, which would allow for local but not global cooling."[38]

Currently the Earth is absorbing ~1 W m2 more than it is emitting, which leads to an overall warming of the climate. By covering a small fraction of the Earth with 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 Earth (...) If only 1%–2% of the Earth’s surface were instead made to radiate at this rate rather than its current average value, the total heat fluxes into and away from the entire Earth would be balanced and warming would cease.[12] The estimated total surface area coverage is 5×1012 m2 or about half the size of the Sahara Desert.[38]

— Jeremy Munday

Desert climates have the highest radiative cooling potential due to low year-round humidity and cloud cover, while tropical climates have less potential due to higher humidity and cloud cover.[5][39] Costs for global implementation have been estimated at $1.25 to $2.5 trillion or about 3% of global GDP, with expected economies of scale.[38] Low-cost scalable materials have been developed for widescale implementation, although some challenges toward commercialization remain.[40][41]

Some studies recommended efforts to maximize solar reflectance or albedo of surfaces, with a goal of thermal emittance of 90%. For example, increasing reflectivity from 0.2 (typical rooftop) to 0.9 is far more impactful than improving an already reflective surface, such as from 0.9 to 0.97.[10]

Benefits

[edit]

Studies have reported many PDRC benefits:

Other geoengineering approaches

[edit]

PDRC has been claimed to be more stable, adaptable, and reversible than stratospheric aerosol injection (SAI).[45]

Wang et al. claimed that SAI "might cause potentially dangerous threats to the Earth’s basic climate operations" that may not be reversible, and thus preferred PDRC.[46] Munday noted that although "unexpected effects will likely occur" with the global implementation of PDRC, that "these structures can be removed immediately if needed, unlike methods that involve dispersing particulate matter into the atmosphere, which can last for decades."[38]

When compared to the reflective surfaces approach of increasing surface albedo, such as through painting roofs white, or the space mirror proposals of "deploying giant reflective surfaces in space", Munday claimed that "the increased reflectivity likely falls short of what is needed and comes at a high financial cost."[38] PDRC differs from the reflective surfaces approach by "increasing the radiative heat emission from the Earth rather than merely decreasing its solar absorption".[38]

Function

[edit]
PDRCs maximize outgoing infrared radiation (shown in orange) and minimize the absorption of Solar Radiation (shown in yellow).

The basic measure of PDRCs is their solar reflectivity (in 0.4–2.5 μm) and heat emissivity (in 8–13 μm),[2] to maximize "net emission of longwave thermal radiation" and minimize "absorption of downward shortwave radiation".[5] PDRCs use the infrared window (8–13 μm) for heat transfer with the coldness of outer space (~2.7 K) to radiate heat and subsequently lower ambient temperatures with zero energy input.[5]

PDRCs mimic the natural process of radiative cooling, in which the Earth cools itself by releasing heat to outer space (Earth's energy budget), although during the daytime, lowering ambient temperatures under direct solar intensity.[5] On a clear day, solar irradiance can reach 1000 W/m2 with a diffuse component between 50 and 100 W/m2. As of 2022 the average PDRC had a cooling power of ~100–150 W/m2.[20] Cooling power is proportional to the installation's surface area.[15]

Measuring effectiveness

[edit]

The most useful measurements come in a real-world setting. Standardized devices have been proposed.[47]

Evaluating atmospheric downward longwave radiation based on "the use of ambient weather conditions such as the surface air temperature and humidity instead of the altitude-dependent atmospheric profiles," may be problematic since "downward longwave radiation comes from various altitudes of the atmosphere with different temperatures, pressures, and water vapor contents" and "does not have uniform density, composition, and temperature across its thickness."[5]

Broadband emitters (BE) vs. selective emitters (SE)

[edit]
Broadband PDRC emitters emit in both the solar spectrum and the infrared window (8 and 14 μm), while selective PDRC emitters only emit in the infrared window.[20]

Broadband emitters possess high emittance in both the solar spectrum and atmospheric LWIR window (8 to 14 μm), or selective emitters, meaning they only emit longwave infrared radiation.[20]

In theory, selective thermal emitters can achieve higher cooling power.[20] However, selective emitters face challenges in real-world applications that can weaken their performance, such as from dropwise condensation (common even in semi-arid climates) that can accumulate on even hydrophobic surfaces and reduce emission.[48] Broadband emitters outperform selective materials when "the material is warmer than the ambient air, or when its sub-ambient surface temperature is within the range of several degrees".[9]

Each type can be advantageous for certain applications. Broadband emitters may be better for horizontal applications, such as roofs, whereas selective emitters may be more useful on vertical surfaces such as building facades, where dropwise condensation is inconsequential and their stronger cooling power can be achieved.[48]

Broadband emitters can be made angle-dependent to potentially enhance performance.[20] Polydimethylsiloxane (PDMS) is a common broadband emitter.[48] Most PDRC materials are broadband, primarily due to their lower cost and higher performance at above-ambient temperatures.[49]

Hybrid systems

[edit]

Combining PDRCs with other systems may increase their cooling power. When included in a combined thermal insulation, evaporative cooling, and radiative cooling system consisting of "a solar reflector, a water-rich and IR-emitting evaporative layer, and a vapor-permeable, IR-transparent, and solar-reflecting insulation layer," 300% higher[clarification needed] ambient cooling power was demonstrated. This could extend the shelf life of food by 40% in humid climates and 200% in dry climates without refrigeration. The system however requires water "re-charges" to maintain cooling power.[50]

A dual-mode asymmetric photonic mirror (APM) consisting of silicon-based diffractive gratings could achieve all-season cooling, even under cloudy and humid conditions, as well as heating. The cooling power of APM could perform 80% more when compared to standalone radiative coolers. Under cloudy sky, it could achieve 8 °C more cooling and, for heating, 5.7 °C.[51]

Climatic variations

[edit]

The cooling potential of various areas varies primarily based on climate zones, weather patterns, and events. Dry and hot regions generally have higher radiative cooling power (up to 120 W m2), while colder regions or those with high humidity or cloud cover generally have less.[39] Cooling potential changes seasonally due to shifts in humidity and cloud cover.[5] Studies mapping daytime radiative cooling potential have been done for China,[37] India,[52] the United States,[53] and across Europe.[54]

Deserts

[edit]
Desert climates have the highest radiative cooling potential due to low humidity and cloud cover.[5]

Dry regions such as western Asia, north Africa, Australia and the southwestern United States are ideal for PDRC due to the relative lack of humidity and cloud cover across the seasons. The cooling potential for desert regions has been estimated at "in the higher range of 80–110 W m2",[5] and 120 W m2.[39] The Sahara Desert and western Asia is the largest area on earth with such a high cooling potential.[5]

The cooling potential of desert regions is likely to remain relatively unfulfilled due to low population densities, reducing demand for local cooling, despite tremendous cooling potential.[5]

Temperate climates have a moderate to high radiative cooling potential.[5]

Temperate climates

[edit]

Temperate climates have a high radiative cooling potential and greater population density, which may increase interest in PDRCs. These zones tend to be "transitional" zones between dry and humid climates.[5] High population areas in temperate zones may be susceptible to an "overcooling" effect from PDRCs due to temperature shifts from summer to winter, which can be overcome with the modification of PDRCs to adjust for temperature shifts.[20]

Tropics

[edit]
Tropical climates have a lower radiative cooling potential due to high humidity and cloud cover.[5]

While PDRCs have proven successful in temperate regions, reaching the same level of performance is more difficult in tropical climes. This has primarily been attributed to the higher solar irradiance and atmospheric radiation, particularly humidity and cloud cover.[17] The average cooling potential of tropical climates varies between 10 and 40 W m2, significantly lower than hot and dry climates.[5]

For example, the cooling potential of most of southeast Asia and the Indian subcontinent is significantly diminished in the summer due to a dramatic increase in humidity, dropping as low as 10–30 W/m2. Other similar zones, such as tropical savannah areas in Africa, see a more modest decline during summer, dropping to 20–40 W/m2. However, tropical regions generally have a higher albedo or radiative forcing due to sustained cloud cover and thus their land surface contributes less to planetary albedo.[5]

A 2022 study reported that a PDRC surface in tropical climates should have a solar reflectance of at least 97% and an infrared emittance of at least 80% to reduce temperatures. The study applied a BaSO4-K
2
SO
4
coating with a "solar reflectance and infrared emittance (8–13 μm) of 98.4% and 95% respectively" in the tropical climate of Singapore and achieved a "sustained daytime sub-ambient temperature of 2°C" under direct solar intensity of 1000 W m2.[17]

Variables

[edit]

Humidity and cloud coverage

[edit]
Global map of cloud cover. Data taken from 2002 to 2015. The darker the color, the clearer the sky.

Humidity and cloud coverage significantly weaken PDRC effectiveness.[7] A 2022 study noted that "vertical variations of both vapor concentration and temperature in the atmosphere" can have a considerable impact on radiative coolers. The authors reported that aerosol and cloud coverage can weaken the effectiveness of radiators and thus concluded that adaptable "design strategies of radiative coolers" are needed to maximize effectiveness under these climatic conditions.[18]

Dropwise condensation

[edit]

The formation of dropwise condensation on PDRC surfaces can alter the infrared emittance of selective PDRC emitters, which can weaken their performance. Even in semi-arid environments, dew formation. Another 2022 study reported that the cooling power of selective emitters "may broaden the narrowband emittances of the selective emitter and reduce their sub-ambient cooling power and their supposed cooling benefits over broadband emitters"[48] and that:

Our work shows that the assumed benefits of selective emitters are even smaller when it comes to the largest application of radiative cooling – cooling roofs of buildings. However, recently, it has been shown that for vertical building facades experiencing broadband summertime terrestrial heat gains and wintertime losses, selective emitters can achieve seasonal thermoregulation and energy savings. Since dew formation appears less likely on vertical surfaces even in exceptionally humid environments, the thermoregulatory benefits of selective emitters will likely persist in both humid and dry operating conditions.[48]

Rain

[edit]
Global map of average annual precipitation. The darker the color, the higher the precipitation.

Rain can generally help clean PDRC surfaces covered with dust, dirt, or other debris. However, in humid areas, consistent rain can result in water accumulation that can hinder performance. Porous PDRCs can mitigate these conditions.[55] Another response is to make hydrophobic self-cleaning PDRCs. Scalable and sustainable hydrophobic PDRCs that avoid VOCs can repel rainwater and other liquids.[56]

Wind

[edit]

Wind may alter the efficiency of passive radiative cooling surfaces and technologies. A 2020 study proposed using a "tilt strategy and wind cover strategy" to mitigate wind effects. The researchers reported regional differences in China, noting that "85% of China's areas can achieve radiative cooling performance with wind cover" whereas in northwestern China wind cover effects would be more substantial.[19] Bijarniya et al. similarly proposes the use of a wind shield in areas susceptible to high winds.[7]

Materials and production

[edit]

PDRC surfaces can be made of various materials. However, for widespread application, PDRC materials must be low cost, available for mass production, and applicable in many contexts. Most research has focused on coatings and thin films, which tend to be more available for mass production, lower cost, and more applicable in a wider range of contexts, although other materials may provide potential for specific applications.[40][41][57][58]

PDRC research has identified more sustainable material alternatives, even if not fully biodegradable.[34][59][60][61][62] A 2023 study reported that "most PDRC materials now are non-renewable polymers, artificial photonic or synthetic chemicals, which will cause excessive CO2 emissions by consuming fossil fuels and go against the global carbon neutrality goal. Environmentally friendly bio-based renewable materials should be an ideal material to devise PDRC systems."[63]

Multilayer and complex structures

[edit]

Advanced photonic materials and structures, such as multilayer thin films, micro/nanoparticles, photonic crystals, metamaterials, and metasurfaces, have been reported as potential approaches.[64] However, while multilayer and complex nano-photonic structures have proven successful in experimental scenarios and simulations, a 2022 study reorted that widespread application "is severely restricted because of the complex and expensive processes of preparation".[41] Similarly, a 2020 study reported that "scalable production of artificial photonic radiators with complex structures, outstanding properties, high throughput, and low cost is still challenging".[65] This has advanced research of simpler structures for PDRC materials possibly better suited for mass production.[64]

Coatings

[edit]
A scalable colored PDRC coating using Bismuth oxide (pictured) was developed by Zhai et al.[30]

PDRC coatings such as paints may be advantageous given their direct application to surfaces, simplifying preparation and reducing costs,[41] although not all coatings are inexpensive.[66] A 2022 study stated that coatings generally offer "strong operability, convenient processing, and low cost, which have the prospect of large-scale utilization".[40] PDRC coatings have been developed in colors other than white while still demonstrating high solar reflectance and heat emissivity.[30]

Coatings must be durable and resistant to soiling, which can be achieved with porous PDRCs[55] or hydrophobic topcoats that can withstand cleaning, although hydrophobic coatings use polytetrafluoroethylene or similar compounds to be water-resistant.[66] Negative environmental impacts can be mitigated by limiting use of other toxic solvents common in paints, such as acetone. Non-toxic or water-based paints have been developed.[66][60]

Porous Polymers Coating (PPC) exhibit excellent PDRC performance. These polymers have a high concentration of tiny pores, which scatter light effectively at the boundary between the polymer and the air. This scattering enhances both solar reflectance (more than 96%) and thermal emittance (97% of heat), lowering surface temperatures six degrees below the surroundings at noon in Phoenix. This process is solution-based, aiding scalability.[67][68] Dye of the desired color is coated on the polymer. Compared to traditional dye in porous polymer, in which the dye is mixed in the polymer, the new design can cool more effectively.[69]

A 2018 study reported significantly lowered coating costs, stating that "photonic media, when properly randomized to minimize the photon transport mean free path, can be used to coat a black substrate and reduce its temperature by radiative cooling." This coating could "outperform commercially available solar-reflective white paint for daytime cooling" without expensive manufacturing steps or materials.[70]

Candidate coatings
Coating Reflectance Emittance Temperature reduction Commercial coating Notes
Aluminum phosphate 97% 90% ~4.2 °C ~4.8 °C predicted estimated cost by Dong et al. at $1.2/m2,[40] tested in Guangzhou (daytime humidity 41%), selective emitter (SE).[71]
Ultrawhite BaSO4 98.1% 95% ~4.5 °C paint with 60% volume concentration, "providing great reliability, convenient paint form, ease of use, and compatibility with the commercial paint fabrication process."[72]
Porous Polydimethylsiloxane 95% 96.5% ~8 °C sponge emitter template method for coatings, avoids hazardous etching agents (e.g., hydrofluoric acid, hydrogen peroxide, acetic acid) or VOCs (e.g., acetone, dimethylformamide, tetrahydrofuran, hexane), "compatibility with large-scale production," tested in Hangzhou (daytime humidity ~61%).[55]
Waterborne thermochromic 96% 94% ~7.1 °C free of ecotoxic and carcinogenic titanium dioxide "can be produced at a large scale and conveniently coated on various substrates through traditional drop casting, spraying, roller painting, or spin-coating methods" and "switchable [between] solar heating and radiative cooling," tested in Shanghai (daytime humidity ~28%).[60]
Barium sulphate, Calcium carbonate, and Silicon dioxide particle coating 97.6% 89% ~8.3 °C ~5.5 °C lower than white paints "for large-scale commercial production" with a predicted estimated cost of $0.5/m2, tested in Weihai (daytime humidity 40%).[40]
α-Bismuth(III) oxide 99% 97% ~2.31 °C Average cooling power 68 W/m2 "low cost of raw oxide materials, and simple preparation process," tested in Nanjing (daytime humidity 54%).[30]

Films

[edit]
A photonic radiator film based on the longicorn beetle Neocerambyx gigas exhibited 95% solar irradiance and 96% emissivity.[65]

Many thin films offer high solar reflectance and heat emittance. However, films with precise patterns or structures are not scalable "due to the cost and technical difficulties inherent in large-scale precise lithography" (2022),[9] or "due to complex nanoscale lithography/synthesis and rigidity" (2021).[73]

The polyacrylate hydrogel film[74] from the 2022 study has broader applications, including potential uses in building construction and large-scale thermal management systems. This research focused on a film developed for hybrid passive cooling. The film uses sodium polyacrylate, a low-cost industrial material, to achieve high solar reflectance and high mid-infrared emittance. A significant feature of this material is its ability to absorb atmospheric moisture, aiding evaporative cooling. This tripartite mechanism allows for efficient cooling under varying atmospheric conditions, including high humidity or given limited access to clear skies.[74]

Candidates
Coating Reflectance Emittance Temperature reduction Commercial coating Notes
Facile microstamping method film on low-cost polymer PDMS 95% 96% 5.1 °C "promising for scale-up production."[65]
phase inversion process using cellulose acetate and calcium silicate 97.3% 97.2% 7.3 °C 90.7 W m−2), "a low-cost, scalable composite film with novel dendritic cell like structures," tested in Qingdao.[75]
Superhydrophobic porous (PDMS) 11.52 °C "the film is promising to be widely used for long-term cooling for outdoor applications."[62]
Fluorine-free reagents and SiO2 particle composite film 85% 95% 12.2 °C manufactured with "a simple preparation process, which has characteristics of low-cost environmental friendliness and excellent machinal durability," tested in Hubei.[59]
Hierarchical flexible fibrous cellulose (wood pulp) film 93.8% 98.3% to 11.3 °C "the first time to realize high crystallinity and hierarchical microstructures in regenerated cellulose materials by the self-assembly of cellulose macromolecules at the molecular level," which "will provide new perspectives for the development of flexible cellulose materials."[63]
Periodic pyramid-textured PDMS radiative film 2 °C. commercial silicon solar cells[76]
Nanoporous anodic aluminum oxide film Improved flat solar cell efficiency by ~2.72%, concentrated solar cell by ~16.02%.[77]

Metafabrics

[edit]

PDRCs can be made of metafabrics, which can be used in clothing to shield/regulate body temperatures. Most metafabrics are made of petroleum-based fibers.[78] For instance, 2023 study reported that a that "new flexible cellulose fibrous films with wood-like hierarchical microstructures need to be developed for wearable PDRC applications."[63]

A 2021 study chose a composite of titanium oxide and polylactic acid (TiO2-PLA) with a polytetrafluoroethylene (PTFE) lamination. The fabric underwent optical and thermal characterization, measuring like reflectivity and emissivity. Numerical simulations, including Lorenz-Mie theory and Monte Carlo simulations, were crucial in predicting the fabric's performance and guiding optimization. Mechanical testing was conducted to assess the fabric's durability, strength, and practicality.[79]

The study reported exceptional ability to facilitate radiative cooling. The fabric achieved 94.5% emissivity and 92.4% reflectivity. This combination of high emissivity and reflectivity is central to its cooling capabilities, significantly outperforming traditional fabrics. Additionally, the fabric's mechanical properties, including strength, durability, waterproofness, and breathability, confirmed its suitability for clothing.[79][80][81]

Candidates
Coating Reflectance Emittance Notes
Eco-friendly bio-derived regenerable polymer alginate to modify cotton fiber and then in-matrix generate CaCO3 nano- or other micro-particles 90% 97% 5.4ᵒC "fully compatible with industrial processing facilities" and with "effective UV protection properties with a UPF value of 15, is fast-dry, and is stable against washing."[78]
Wearable hat constructed of a radiative cooling paper with SiO2 fibers and fumed SiO2 97% 91% reduced temperatures for the hair of the wearer by 12.9ᵒC when compared with a basic white cotton hat (and 19ᵒC when compared with no hat), waterproof and air permeable, "suitable for the manufacture of radiative cooling hat to achieve the thermal management of human head."[82]

Aerogels

[edit]

Aerogels offer a potential low-cost material scalable for mass production. Some aerogels can be considered a more environmentally friendly alternative to other materials, with degradable potential and the absence of toxic chemicals.[83][61] Aerogels can be useful as thermal insulation to reduce solar absorption and parasitic heat gain to improve the cooling performance of PDRCs.[84]

Candidates
Coating Reflectance Emittance Temperature reduction Notes
Superhydrophobic waste paper-based (cellulose) aerogel 93% 91% 8.5 °C n a building energy simulation the aerogel "showed that 43.4% of cooling energy on average could be saved compared to the building baseline consumption" in China if widely implemented.[85]
Degradable and superhydrophobic stereo-complex poly (lactic acid) aerogel with low thermal conductivity 89% 93% 3.5ᵒC "opens an environmentally sustainable pathway to radiative cooling applications."[61]
Low-cost silica-alumina nanofibrous aerogels (SAFAs) synthesized by electrospinning 95% 93% 5ᵒC "the SAFAs exhibit high compression fatigue resistance, robust fire resistance and excellent thermal insulation" with "low cost and high performance," shows potential for further studies.[83]
Clear SiO2 aerogel 7.7 °C Used an optical modulator (n-hexadecane) in microparticles within a silicone elastomer matrix. Commercial silicon solar cells.[86]

Nano bubbles

[edit]

Pigments absorb light. Soap bubbles show a prism of different colors on their surfaces. These colors result from the way light interacts with differing thicknesses of the bubble's surface, termed structural color. One study reported that cellulose nanocrystals (CNCs), which are derived from the cellulose found in plants, could be made into iridescent, colorful films without added pigment. They made films with blue, green and red colors that, when placed under sunlight, were an average of nearly 7ᵒF cooler than the surrounding air. The film generated over 120 W m-2 of cooling power.[87]

Biodegradable surfaces

[edit]

Many proposed radiative cooling materials are not biodegradable. A 2022 study reported that "sustainable materials for radiative cooling have not been sufficiently investigated."[34]

Candidates
Coating Reflectance Emittance Temperature reduction Notes
Eco-friendly porous polymer structure via thermally induced phase separation 91% 92% 9 °C sufficient durability for use on buildings and highest cooling effect reported "among all organic-based passive radiation cooling emitters."[34]

Micro-grating

[edit]

A silica micro-grating photonic device cooled commercial silicon cells by 3.6 °C under solar intensity of 830 W m−2 to 990 W m−2.[88]

Applications

[edit]

Passive daytime radiative cooling has "the potential to simultaneously alleviate the two major problems of energy crisis and global warming"[1] along with an "environmental protection refrigeration technology."[40] PDRCs have an array of potential applications, but are now most often applied to various aspects of the built environment, such as building envelopes, cool pavements, and other surfaces to decrease energy demand, costs, and CO2 emissions.[89] PDRC has been applied for indoor space cooling, outdoor urban cooling, solar cell efficiency, power plant condenser cooling, among other applications.[7][15][33] For outdoor applications, PDRC durability is an important requirement.[49]

Indoor space cooling

[edit]
Single-family detached homes in the US suburbs are estimated to lower energy costs by 26% to 46% with PDRC implementation.[90]

The most common application is on building envelopes, including cool roofs. A PDRC can double the energy savings of a white roof.[15] This makes PDRCs an alternative or supplement to air conditioning that lowers energy demand and reduces air conditioning's release of hydrofluorocarbons (HFC) into the atmosphere. HFCs can be thousands of times more potent than CO2.[7][15][41][8]

Air conditioning accounts for 12%-15% of global energy usage,[7][78] while CO2 emissions from air conditioning account for "13.7% of energy-related CO2 emissions, approximately 52.3 EJ yearly"[40] or 10% of total emissions.[78] Air conditioning applications are expected to rise.[30] However, this can be significantly reduced with the mass production of low-cost PDRCs for indoor space cooling.[7][8][91] A multilayer PDRC surface covering 10% of a building's roof can replace 35% of air conditioning used during the hottest hours of daytime.[7]

In suburban single-family residential areas, PDRCs can lower energy costs by 26% to 46% in the United States[90] and lower temperatures on average by 5.1ᵒC. With the addition of "cold storage to utilize the excess cooling energy of water generated during off-peak hours, the cooling effects for indoor air during the peak-cooling-load times can be significantly enhanced" and air temperatures may be reduced by 6.6–12.7 °C.[92]

In cities, PDRCs can produce significant energy and cost savings. In a study on US cities, Zhou et al. found that "cities in hot and arid regions can achieve high annual electricity consumption savings of >2200 kWh, while <400 kWh is attainable in colder and more humid cities," ranking from highest to lowest by electricity consumption savings as follows: Phoenix (~2500 kWh), Las Vegas (~2250 kWh), Austin (~2100 kWh), Honolulu (~2050 kWh), Atlanta (~1500 kWh), Indianapolis (~1200 kWh), Chicago (~1150 kWh), New York City (~900 kWh), Minneapolis (~850 kWh), Boston (~750 kWh), Seattle (~350 kWh).[92] In a study projecting energy savings for Indian cities in 2030, Mumbai and Kolkata had a lower energy savings potential, Jaisalmer, Varansai, and Delhi had a higher potential, although with significant variations from April to August dependent on humidity and wind cover.[52]

The growing interest and rise in PDRC application to buildings has been attributed to cost savings related to "the sheer magnitude of the global building surface area, with a market size of ~$27 billion in 2025," as estimated in a 2020 study.[89]

Outdoor urban space cooling

[edit]
A PDRC installed on a roof in Kolkata exhibited a nearly 4.9 °C (8.8 °F) decrease in surface ground temperatures (with an average reduction of 2.2 °C or 4.0 °F).[9]

PDRC surfaces can mitigate extreme heat from the urban heat island effect that occurs in over 450 cities worldwide. It can be as much as 10–12 °C (18–22 °F) hotter in urban areas than nearby rural areas.[9][10] On an average hot summer day, the roofs of buildings can be 27–50 °C (49–90 °F) hotter than the surrounding air, warming air temperatures further through convection. Well-insulated dark rooftops are significantly hotter than all other urban surfaces, including asphalt pavements,[10] further expanding air conditioning demand (which further accelerates global warming and urban heat island through the release of waste heat into the ambient air) and increasing risks of heat-related disease and fatal health effects.[9][43][44]

PDRCs can be applied to building roofs and urban shelters to significantly lower surface temperatures with zero energy consumption by reflecting heat out of the urban environment and into outer space.[9][10] The primary obstacle to PDRC implementation is the glare that may be caused through the reflection of visible light onto surrounding buildings. Colored PDRC surfaces may mitigate glare.[66] such as Zhai et al.[30] "Super-white paints with commercial high-index (n~1.9) retroreflective spheres",[66] or the use of retroreflective materials (RRM) may also mitigate glare.[10] Surrounding buildings without PDRC may weaken the cooling power of PDRCs.[90]

Even when installed on roofs in highly dense urban areas, broadband radiative cooling panels lower surface temperatures at the sidewalk level.[93] A 2022 study assessed the effects of PDRC surfaces in winter, including non-modulated and modulated PDRCs, in the Kolkata metropolitan area. A non-modulated PDRC with a reflectance of 0.95 and emissivity of 0.93 decreased ground surface temperatures by nearly 4.9 °C (8.8 °F) and with an average daytime reduction of 2.2 °C (4.0 °F).[9]

While in summer the cooling effects of broadband non-modulated PDRCs may be desirable, they could present an uncomfortable "overcooling" effect for city populations in winter and thus increase energy use for heating. This can be mitigated by broadband modulated PDRCs, which they found could increase daily ambient urban temperatures by 0.4–1.4 °C (0.72–2.52 °F) in winter. While in Kolkata "overcooling" is unlikely, elsewhere it could have unwanted impacts. Therefore, modulated PDRCs may be preferred in cities with warm summers and cold winters for controlled cooling, while non-modulated PDRCs may be more beneficial for cities with hot summers and moderate winters.[9]

In a study on urban bus shelters, it was found that most shelters fail at providing thermal comfort for commuters, while a tree could provide 0.5 °C (0.90 °F) more cooling.[90] Other methods to cool shelters often involve air conditioning or other energy intensive measures. Urban shelters with PDRC roofing can significantly reduce temperatures with zero energy input, while adding "a non-reciprocal mid-infrared cover" can increase benefits by reducing incoming atmospheric radiation as well as reflecting radiation from surrounding buildings.[90]

For outdoor urban space cooling, a 2021 study recommended that PDRC in urban areas primarily focus on increasing albedo so long as emissivity can be maintained above 90%.[10]

Solar energy efficiency

[edit]
Solar cell efficiency can be improved with PDRC application to reduce overheating and degradation of cells.[15]

PDRC surfaces can be integrated with solar energy plants, referred to as solar energy–radiative cooling (SE–RC), to improve functionality and performance by preventing solar cells from 'overheating' and thus degrading. Since silicon solar cells have a maximum efficiency of 33.7% (with the average commercial panel reaching around 20%), the majority of absorbed power produces excess heat and increases the operating temperature.[15][76] Solar cell efficiency declines 0.4-0.5% for every 1 ᵒC increase in temperature.[15]

PDRC can extend the life of solar cells by lowering the operating temperature of the system.[76] Integrating PDRCs into solar energy systems is also relatively simple, given that "most solar energy harvesting systems have a sky-facing flat plate structural design, which is similar to radiative cooling systems." Integration has been reported to increase energy gain per unit area while increasing the fraction of the day the cell operates.[14]

Methods have been proposed to potentially enhance cooling performance. One 2022 study proposed using a "full-spectrum synergetic management (FSSM) strategy to cool solar cells, which combines radiative cooling and spectral splitting to enhance radiative heat dissipation and reduce the waste heat generated by the absorption of sub-BG photons."[94]

Personal thermal management

[edit]

Personal thermal management (PTM) employs PDRC in fabrics to regulate body temperatures during extreme heat. While other fabrics are useful for heat accumulation, they "may lead to heat stroke in hot weather."[95] A 2021 study claimed that "incorporating passive radiative cooling structures into personal thermal management technologies could effectively defend humans against intensifying global climate change."[96]

Wearable PDRCs can come in different forms and target outdoor workers. Products are at the prototype stage.[82][97] Although most textiles are white, colored wearable materials in select colors may be appropriate in some contexts.[15]

Power plant condenser cooling

[edit]

Power plant condensers used in thermoelectric power plants and concentrated solar plants (CSP) can cool water for effective use within the heat exchanger. A study of a pond covered with a radiative cooler reported that 150 W m2 flux could be achieved without loss of water.[7] PDRC can reduce water use and thermal pollution caused by water cooling.[5]

A review reported that supplementing the air-cooled condenser for radiative cooling panels in a thermoelectric power plant condenser achieved a 4096 kWhth/day cooling effect with a pump energy consumption of 11 kWh/day.[7] A concentrated solar plant (CSP) on the CO2 supercritical cycle at 550ᵒC was reported to produce 5% net output gain over an air-cooled system by integration with 14 m2 /kWe capacity radiative cooler."[7]

Thermal regulation of buildings

[edit]

In addition to cooling, PDRC surfaces can be modified for bi-directional thermal regulation (cooling and heating).[9] This can be achieved through switching thermal emittance between high and low values.[9][15]

Thermoelectric generation

[edit]

When combined with a thermoelectric generator, a PDRC surface can generate small amounts of electricity.[15]

Automobile and greenhouse cooling

[edit]

Thermally enclosed spaces, including automobiles and greenhouses, are particularly susceptible to harmful temperature increases. This is because of the heavy presence of windows, which are transparent to incoming solar radiation yet opaque to outgoing long-wave thermal radiation, which causes them to heat rapidly in the sun. Automobile temperatures in direct sunlight can rise to 60–82 ᵒC when ambient temperatures is only 21 ᵒC.[15]

Water harvesting

[edit]

Dew harvesting yields may be improved via with PDRC. Selective PDRC emitters that have a high emissivity and broadband emitters may produce varying results. In one study using a broadband PDRC, the device condensed ~8.5 mL day of water for 800 W m2 of peak solar intensity."[15] Whereas selective emitters may be less advantageous in other contexts, they may be superior for dew harvesting applications.[48] PDRCs could improve atmospheric water harvesting by being combined with solar vapor generation systems to improve water collection rates.[49]

Water and ice cooling

[edit]

PDRC surfaces can be installed over the surface of a body of water for cooling. In a controlled study, a body of water was cooled 10.6 ᵒC below the ambient temperature with the usage of a photonic radiator.[7] [failed verification]

PDRC surfaces have been developed to cool ice and prevent ice from melting under sunlight. It has been proposed as a sustainable method for ice protection. This can also be applied to protect refrigerated food from spoiling.[98]

Side effects

[edit]

Jeremy Munday writes that although "unexpected effects will likely occur", PDRC structures "can be removed immediately if needed, unlike methods that involve dispersing particulate matter into the atmosphere, which can last for decades."[99] Stratospheric aerosol injection "might cause potentially dangerous threats to the Earth’s basic climate operations" that may not be reversible, preferring PDRC.[24] Zevenhoven et al. state that "instead of stratospheric aerosol injection (SAI), cloud brightening or a large number of mirrors in the sky (“sunshade geoengineering”) to block out or reflect incoming (short-wave, SW) solar irradiation, long-wavelength (LW) thermal radiation can be selectively emitted and transferred through the atmosphere into space".[3]

"Overcooling" and PDRC modulation

[edit]
Modifying PDRCs with vanadium dioxide (pictured) can achieve temperature-based 'switching' from cooling to heating to mitigate the "overcooling" effect.[20]

"Overcooling" is cited as a side effect of PDRCs that may be problematic, especially when PDRCs are applied in high-population areas with hot summers and cool winters, characteristic of temperate zones.[20] While PDRC application in these areas can be useful in summer, in winter it can result in an increase in energy consumption for heating and thus may reduce the benefits of PDRCs on energy savings and emissions.[9][21] As per Chen et al., "to overcome this issue, dynamically switchable coatings have been developed to prevent overcooling in winter or cold environments."[20]

The detriments of overcooling can be reduced by modulation of PDRCs, harnessing their passive cooling abilities during summer, while modifying them to passively heat during winter. Modulation can involve "switching the emissivity or reflectance to low values during the winter and high values during the warm period."[9] In 2022, Khan et al. concluded that "low-cost optically modulated" PDRCs are "under development" and "are expected to be commercially available on the market soon with high future potential to reduce urban heat in cities without leading to an overcooling penalty during cold periods."[9]

There are various methods of making PDRCs 'switchable' to mitigate overcooling.[20] Most research has used vanadium dioxide (VO2), an inorganic compound, to achieve temperature-based 'switchable' cooling and heating effects.[20][21] While, as per Khan et al., developing VO2 is difficult, their review found that "recent research has focused on simplifying and improving the expansion of techniques for different types of applications."[9] Chen et al. found that "much effort has been devoted to VO2 coatings in the switching of the mid-infrared spectrum, and only a few studies have reported the switchable ability of temperature-dependent coatings in the solar spectrum."[20] Temperature-dependent switching requires no extra energy input to achieve both cooling and heating.[20]

Other methods of PDRC 'switching' require extra energy input to achieve desired effects. One such method involves changing the dielectric environment. This can be done through "reversible wetting" and drying of the PDRC surface with common liquids such as water and alcohol. However, for this to be implemented on a mass scale, "the recycling, and utilization of working liquids and the tightness of the circulation loop should be considered in realistic applications."[20]

Another method involves 'switching' through mechanical force, which may be useful and has been "widely investigated in [PDRC] polymer coatings owing to their stretchability." For this method, "to achieve a switchable coating in εLWIR, mechanical stress/strain can be applied in a thin PDMS film, consisting of a PDMS grating and embedded nanoparticles." One study estimated, with the use of this method, that "19.2% of the energy used for heating and cooling can be saved in the US, which is 1.7 times higher than the only cooling mode and 2.2 times higher than the only heating mode," which may inspire additional research and development.[20]

Glare and visual appearance

[edit]

Glare caused from surfaces with high solar reflectance may present visibility concerns that can limit PDRC application, particularly within urban environments at the ground level.[30] PDRCs that use a "scattering system" to generate reflection in a more diffused manner have been developed and are "more favorable in real applications," as per Lin et al.[100]

Low-cost PDRC colored paint coatings, which reduce glare and increase the color diversity of PDRC surfaces, have also been developed. While some of the surface's solar reflectance is lost in the visible light spectrum, colored PDRCs can still exhibit significant cooling power, such as a coating by Zhai et al., which used a α-Bi2O3 coating (resembling the color of the compound) to develop a non-toxic paint that demonstrated a solar reflectance of 99% and heat emissivity of 97%.[30]

Generally it is noted that there is a tradeoff between cooling potential and darker colored surfaces. Less reflective colored PDRCs can also be applied to walls while more reflective white PDRCs can be applied to roofs to increase visual diversity of vertical surfaces, yet still contribute to cooling.[31]

History

[edit]
The Saharan silver ant's ability to cool its body temperature in extreme heat inspired early PDRC research.[101]

Nocturnal passive radiative cooling has been recognized for thousands of years, with records showing awareness by the ancient Iranians, demonstrated through the construction of Yakhchāls, since 400 B.C.E.[102]

PDRCwas hypothesized by Félix Trombe in 1967. The first experimental setup was created in 1975, but was only successful for nighttime cooling. Further developments to achieve daytime cooling using different material compositions were not successful.[7]

In the 1980s, Lushiku and Granqvist identified the infrared window as a potential way to access the ultracold outer space as a way to achieve passive daytime cooling.[3]

Early attempts at developing passive radiative daytime cooling materials took inspiration from nature, particularly the Saharan silver ant and white beetles, noting how they cooled themselves in extreme heat.[15][33]

Research and development in PDRCevolved rapidly in the 2010s with the discovery of the ability to suppress solar heating using photonic metamaterials, which widely expanded research and development in the field.[15][33]

In 2024, Nissan introduced a paint that lowers car interior temperatures by up to 21 °F in direct sunlight. It involves two types of particles, each operating at a different frequency. One reflects near-infrared light. The second converts other frequencies to match the infrared window, radiating the energy into space.[103]

See also

[edit]

References

[edit]
  1. ^ a b c d e Chen, Meijie; Pang, Dan; Chen, Xingyu; Yan, Hongjie; Yang, Yuan (2022). "Passive daytime radiative cooling: Fundamentals, material designs, and applications". EcoMat. 4. doi:10.1002/eom2.12153. S2CID 240331557. 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 warming.
  2. ^ a b c Wang, Tong; Wu, Yi; Shi, Lan; Hu, Xinhua; Chen, Min; Wu, Limin (2021). "A structural polymer for highly efficient all-day passive radiative cooling". Nature Communications. 12 (365): 365. doi:10.1038/s41467-020-20646-7. PMC 7809060. PMID 33446648. Accordingly, designing and fabricating efficient PDRC with sufficiently high solar reflectance (𝜌¯solar) (λ ~ 0.3–2.5 μm) to minimize solar heat gain and simultaneously strong LWIR thermal emittance (ε¯LWIR) to maximize radiative heat loss is highly desirable. When the incoming radiative heat from the Sun is balanced by the outgoing radiative heat emission, the temperature of the Earth can reach its steady state.
  3. ^ a b c d e Zevenhovena, Ron; Fält, Martin (June 2018). "Radiative cooling through the atmospheric window: A third, less intrusive geoengineering approach". Energy. 152: 27. Bibcode:2018Ene...152...27Z. doi:10.1016/j.energy.2018.03.084. S2CID 116318678 – via Elsevier Science Direct. An alternative, third geoengineering approach would be enhanced cooling by thermal radiation from the Earth's surface into space." [...] "With 100 W m2 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 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.
  4. ^ a b c Heo, Se-Yeon; Ju Lee, Gil; Song, Young Min (June 2022). "Heat-shedding with photonic structures: radiative cooling and its potential". Journal of Materials Chemistry C. 10 (27): 9915–9937. doi:10.1039/D2TC00318J. S2CID 249695930 – via Royal Society of Chemistry.
  5. ^ a b c d e f g h i j k l m n o p q r s t u v w x Aili, Ablimit; Yin, Xiaobo; Yang, Ronggui (October 2021). "Global Radiative Sky Cooling Potential Adjusted for Population Density and Cooling Demand". Atmosphere. 12 (11): 1379. Bibcode:2021Atmos..12.1379A. doi:10.3390/atmos12111379.
  6. ^ a b Chen, Jianheng; Lu, Lin; Gong, Quan (June 2021). "A new study on passive radiative sky cooling resource maps of China". Energy Conversion and Management. 237: 114132. Bibcode:2021ECM...23714132C. doi:10.1016/j.enconman.2021.114132. S2CID 234839652 – via Elsevier Science Direct. Passive radiative cooling utilizes atmospheric transparency window (8–13 μm) to discharge heat into outer space and inhibits solar absorption.
  7. ^ a b c d e f g h i j k l m n o Bijarniya, Jay Prakash; Sarkar, Jahar; Maiti, Pralay (November 2020). "Review on passive daytime radiative cooling: Fundamentals, recent researches, challenges and opportunities". Renewable and Sustainable Energy Reviews. 133: 110263. Bibcode:2020RSERv.13310263B. doi:10.1016/j.rser.2020.110263. S2CID 224874019 – via Elsevier Science Direct.
  8. ^ a b c Benmoussa, Youssef; Ezziani, Maria; Djire, All-Fousseni; Amine, Zaynab; Khaldoun, Asmae; Limami, Houssame (September 2022). "Simulation of an energy-efficient cool roof with cellulose-based daytime radiative cooling material". Materials Today: Proceedings. 72: 3632–3637. doi:10.1016/j.matpr.2022.08.411. S2CID 252136357 – via Elsevier Science Direct.
  9. ^ a b c d e f g h i j k l m n o Khan, Ansar; Carlosena, Laura; Feng, Jie; Khorat, Samiran; Khatun, Rupali; Doan, Quang-Van; Santamouris, Mattheos (January 2022). "Optically Modulated Passive Broadband Daytime Radiative Cooling Materials Can Cool Cities in Summer and Heat Cities in Winter". Sustainability. 14 – via MDPI.
  10. ^ a b c d e f g h Anand, Jyothis; Sailor, David J.; Baniassadi, Amir (February 2021). "The relative role of solar reflectance and thermal emittance for passive daytime radiative cooling technologies applied to rooftops". Sustainable Cities and Society. 65: 102612. Bibcode:2021SusCS..6502612A. doi:10.1016/j.scs.2020.102612. S2CID 229476136 – via Elsevier Science Direct.
  11. ^ a b c d e f g Liang, Jun; Wu, Jiawei; Guo, Jun; Li, Huagen; Zhou, Xianjun; Liang, Sheng; Qiu, Cheng-Wei; Tao, Guangming (September 2022). "Radiative cooling for passive thermal management towards sustainable carbon neutrality". National Science Review. 10 (1): nwac208. doi:10.1093/nsr/nwac208. PMC 9843130. PMID 36684522.
  12. ^ a b Munday, Jeremy (2019). "Tackling Climate Change through Radiative Cooling". Joule. 3 (9): 2057–2060. Bibcode:2019Joule...3.2057M. doi:10.1016/j.joule.2019.07.010. S2CID 201590290. 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 Earth.
  13. ^ Yin, Xiaobo; Yang, Ronggui; Tan, Gang; Fan, Shanhui (November 2020). "Terrestrial radiative cooling: Using the cold universe as a renewable and sustainable energy source". Science. 370 (6518): 786–791. Bibcode:2020Sci...370..786Y. doi:10.1126/science.abb0971. PMID 33184205. S2CID 226308213. ...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.
  14. ^ a b c d e Ahmed, Salman; Li, Zhenpeng; Javed, Muhammad Shahzad; Ma, Tao (September 2021). "A review on the integration of radiative cooling and solar energy harvesting". Materials Today: Energy. 21: 100776. Bibcode:2021MTEne..2100776A. doi:10.1016/j.mtener.2021.100776 – via Elsevier Science Direct.
  15. ^ a b c d e f g h i j k l m n o p q r s Heo, Se-Yeon; Ju Lee, Gil; Song, Young Min (June 2022). "Heat-shedding with photonic structures: radiative cooling and its potential". Journal of Materials Chemistry C. 10 (27): 9915–9937. doi:10.1039/D2TC00318J. S2CID 249695930 – via Royal Society of Chemistry.
  16. ^ Munday, Jeremy (2019). "Tackling Climate Change through Radiative Cooling". Joule. 3 (9): 2057–2060. Bibcode:2019Joule...3.2057M. doi:10.1016/j.joule.2019.07.010. S2CID 201590290. If only 1%–2% of the Earth's surface were instead made to radiate at this rate rather than its current average value, the total heat fluxes into and away from the entire Earth would be balanced and warming would cease.
  17. ^ a b c Han, Di; Fei, Jipeng; Li, Hong; Ng, Bing Feng (August 2022). "The criteria to achieving sub-ambient radiative cooling and its limits in tropical daytime". Building and Environment. 221 (1): 109281. Bibcode:2022BuEnv.22109281H. doi:10.1016/j.buildenv.2022.109281 – via Elsevier Science Direct.
  18. ^ a b Huang, Jingyuan; Lin, Chongjia; Li, Yang; Huang, Baoling (May 2022). "Effects of humidity, aerosol, and cloud on subambient radiative cooling". International Journal of Heat and Mass Transfer. 186: 122438. Bibcode:2022IJHMT.18622438H. doi:10.1016/j.ijheatmasstransfer.2021.122438. S2CID 245805048 – via Elsevier Science Direct.
  19. ^ a b Liu, Junwei; Zhang, Ji; Zhang, Debao; Jiao, Shifei; Xing, Jingcheng; Tang, Huajie; Zhang, Ying; Li, Shuai; Zhou, Zhihua; Zuo, Jian (September 2020). "Sub-ambient radiative cooling with wind cover". Renewable and Sustainable Energy Reviews. 130: 109935. Bibcode:2020RSERv.13009935L. doi:10.1016/j.rser.2020.109935. S2CID 219911962 – via Elsevier Science Direct.
  20. ^ a b c d e f g h i j k l m n o p Chen, Meijie; Pang, Dan; Chen, Xingyu; Yan, Hongjie; Yang, Yuan (2022). "Passive daytime radiative cooling: Fundamentals, material designs, and applications". EcoMat. 4. doi:10.1002/eom2.12153. S2CID 240331557.
  21. ^ a b c Wang, Zhaochen; Kim, Sun-Kyung; Hu, Run (March 2022). "Self-switchable radiative cooling". Matter. 5 (3): 780–782. doi:10.1016/j.matt.2022.01.018. S2CID 247329090.
  22. ^ Yang, Yuan; Zhang, Yifan (2020). "Passive daytime radiative cooling: Principle, application, and economic analysis". MRS Energy & Sustainability. 7 (18). doi:10.1557/mre.2020.18. S2CID 220008145. Archived from the original on 27 September 2022. Retrieved 27 September 2022.
  23. ^ "What is 3M Passive Radiative Cooling?". 3M. Archived from the original on 22 September 2021. Retrieved 27 September 2022. Passive Radiative Cooling is a natural phenomenon that only occurs at night in nature because all nature materials absorb more solar energy during the day than they are able to radiate to the sky.
  24. ^ a b Wang, Tong; Wu, Yi; Shi, Lan; Hu, Xinhua; Chen, Min; Wu, Limin (2021). "A structural polymer for highly efficient all-day passive radiative cooling". Nature Communications. 12 (365): 365. doi:10.1038/s41467-020-20646-7. PMC 7809060. PMID 33446648. Accordingly, designing and fabricating efficient PDRC with sufficiently high solar reflectance (𝜌¯solar) (λ ~ 0.3–2.5 μm) to minimize solar heat gain and simultaneously strong LWIR thermal emittance (ε¯LWIR) to maximize radiative heat loss is highly desirable. When the incoming radiative heat from the Sun is balanced by the outgoing radiative heat emission, the temperature of the Earth can reach its steady state.
  25. ^ Yu, Xinxian; Yao, Fengju; Huang, Wenjie; Xu, Dongyan; Chen, Chun (July 2022). "Enhanced radiative cooling paint with broken glass bubbles". Renewable Energy. 194: 129–136. Bibcode:2022REne..194..129Y. doi:10.1016/j.renene.2022.05.094. S2CID 248972097 – via Elsevier Science Direct. Radiative cooling does not consume external energy but rather harvests coldness from outer space as a new renewable energy source.
  26. ^ Ma, Hongchen (2021). "Flexible Daytime Radiative Cooling Enhanced by Enabling Three-Phase Composites with Scattering Interfaces between Silica Microspheres and Hierarchical Porous Coatings". ACS Appl. Mater. Interfaces. 13 (16): 19282–19290. arXiv:2103.03902. doi:10.1021/acsami.1c02145. PMID 33866783. S2CID 232147880 – via ACS Publications. Daytime radiative cooling has attracted considerable attention recently due to its tremendous potential for passively exploiting the coldness of the universe as clean and renewable energy.
  27. ^ Aili, Ablimit; Yin, Xiaobo; Yang, Ronggui (October 2021). "Global Radiative Sky Cooling Potential Adjusted for Population Density and Cooling Demand". Atmosphere. 12 (11): 1379. Bibcode:2021Atmos..12.1379A. doi:10.3390/atmos12111379.
  28. ^ Heo, Se-Yeon; Ju Lee, Gil; Song, Young Min (June 2022). "Heat-shedding with photonic structures: radiative cooling and its potential". Journal of Materials Chemistry C. 10 (27): 9915–9937. doi:10.1039/D2TC00318J. S2CID 249695930 – via Royal Society of Chemistry.
  29. ^ Chen, Meijie; Pang, Dan; Chen, Xingyu; Yan, Hongjie; Yang, Yuan (2022). "Passive daytime radiative cooling: Fundamentals, material designs, and applications". EcoMat. 4. doi:10.1002/eom2.12153. S2CID 240331557.
  30. ^ a b c d e f g h Zhai, Huatian; Fan, Desong; Li, Qiang (September 2022). "Scalable and paint-format colored coatings for passive radiative cooling". Solar Energy Materials and Solar Cells. 245: 111853. Bibcode:2022SEMSC.24511853Z. doi:10.1016/j.solmat.2022.111853. S2CID 249877164 – via Elsevier Science Direct.
  31. ^ a b Dang, Saichao; Xiang, Jingbo; Yao, Hongxin; Yang, Fan; Ye, Hong (March 2022). "Color-preserving daytime passive radiative cooling based on Fe3+-doped Y2Ce2O7". Energy and Buildings. 259: 111861. Bibcode:2022EneBu.25911861D. doi:10.1016/j.enbuild.2022.111861. S2CID 246105880 – via Elsevier Science Direct.
  32. ^ Raman, Aaswath P.; Anoma, Marc Abou; Zhu, Linxiao; Raphaeli, Eden; Fan, Shanhui (2014). "Passive Radiative Cooling Below Ambient air Temperature under Direct Sunlight". Nature. 515 (7528): 540–544. Bibcode:2014Natur.515..540R. doi:10.1038/nature13883. PMID 25428501. S2CID 4382732 – via nature.com.
  33. ^ a b c d e f g Banik, Udayan; Agrawal, Ashutosh; Meddeb, Hosni; Sergeev, Oleg; Reininghaus, Nies; Götz-Köhler, Maximilian; Gehrke, Kai; Stührenberg, Jonas; Vehse, Martin; Sznajder, Maciej; Agert, Carsten (2021). "Efficient Thin Polymer Coating as a Selective Thermal Emitter for Passive Daytime Radiative Cooling". ACS Applied Materials & Interfaces. 13 (20): 24130–24137. doi:10.1021/acsami.1c04056. PMID 33974398. S2CID 234471290 – via ACS Publications.
  34. ^ a b c d Park, Chanil; Park, Choyeon; Nie, Xiao; Lee, Jaeho; Kim, Yong Seok; Yoo, Youngjae (2022). "Fully Organic and Flexible Biodegradable Emitter for Global Energy-Free Cooling Applications". ACS Sustainable Chemistry & Engineering. 10 (21): 7091–7099. doi:10.1021/acssuschemeng.2c01182 – via ACS Publications.
  35. ^ Miranda, Nicole D.; Renaldi, Renaldi; Khosla, Radhika; McCulloch, Malcolm D. (October 2021). "Bibliometric analysis and landscape of actors in passive cooling research". Renewable and Sustainable Energy Reviews. 149: 111406. Bibcode:2021RSERv.14911406M. doi:10.1016/j.rser.2021.111406 – via Elsevier Science Direct. In the last three years, however, publications on radiative cooling and solar control have been the most numerous and hence are promising technologies in the field.
  36. ^ a b Chen, Guoliang; Wang, Yaming; Qiu, Jun; Cao, Jianyun; Zou, Yongchun; Wang, Shuqi; Jia, Dechang; Zhou, Yu (August 2021). "A facile bioinspired strategy for accelerating water collection enabled by passive radiative cooling and wettability engineering". Materials & Design. 206: 109829. doi:10.1016/j.matdes.2021.109829. S2CID 236255835.
  37. ^ a b Chang, Kai; Zhang, Qingyuan (2019). "Modeling of downward longwave radiation and radiative cooling potential in China". Journal of Renewable and Sustainable Energy. 11 (6): 066501. doi:10.1063/1.5117319. hdl:10131/00012884. S2CID 209774036.
  38. ^ a b c d e f g h i Munday, Jeremy (2019). "Tackling Climate Change through Radiative Cooling". Joule. 3 (9): 2057–2060. Bibcode:2019Joule...3.2057M. doi:10.1016/j.joule.2019.07.010. S2CID 201590290.
  39. ^ a b c Yin, Xiaobo; Yang, Ronggui; Tan, Gang; Fan, Shanhui (November 2020). "Terrestrial radiative cooling: Using the cold universe as a renewable and sustainable energy source". Science. 370 (6518): 786–791. Bibcode:2020Sci...370..786Y. doi:10.1126/science.abb0971. PMID 33184205. S2CID 226308213.
  40. ^ a b c d e f g Dong, Yan; Han, Han; Wang, Fuqiang; Zhang, Yingjie; Cheng, Ziming; Shi, Xuhang; Yan, Yujing (June 2022). "A low-cost sustainable coating: Improving passive daytime radiative cooling performance using the spectral band complementarity method". Renewable Energy. 192: 606–616. Bibcode:2022REne..192..606D. doi:10.1016/j.renene.2022.04.093 – via Elsevier Science Direct.
  41. ^ a b c d e Cui, Yan; Luo, Xianyu; Zhang, Fenghua; Sun, Le; Jin, Nuo; Yang, Weiman (August 2022). "Progress of passive daytime radiative cooling technologies towards commercial applications". Particuology. 67: 57–67. doi:10.1016/j.partic.2021.10.004. S2CID 243468810 – via Elsevier Science Direct.
  42. ^ Lv, Jinpeng; Chen, Zhuo; Li, Xingji (April 2022). "Calcium Phosphate Paints for Full-Daytime Subambient Radiative Cooling". ACS Applied Energy Materials. 5 (4): 4117–4124. doi:10.1021/acsaem.1c03457. S2CID 247986320 – via ACS Publications. Passive radiative cooling is of great significance for energy-saving and global carbon neutrality because of its zero energy consumption, no pollution, and low cost.
  43. ^ a b Chen, Meijie; Pang, Dan; Yan, Hongjie (November 2022). "Colored passive daytime radiative cooling coatings based on dielectric and plasmonic spheres". Applied Thermal Engineering. 216: 119125. Bibcode:2022AppTE.21619125C. doi:10.1016/j.applthermaleng.2022.119125. S2CID 251420566 – via Elsevier Science Direct. One such promising alternative is radiative cooling, which is a ubiquitous process of losing surface heat through thermal radiation. Instead of releasing waste heat into ambient air as conventional cooling systems, radiative cooling passively discharges it into outer space.
  44. ^ a b Kovats, Sari; Brisley, Rachel (2021). Betts, R.A.; Howard, A.B.; Pearson, K.V. (eds.). "Health, Communities and the Built Environment" (PDF). The Third UK Climate Change Risk Assessment Technical Report. Prepared for the Climate Change Committee, London: 38. Although uptake may increase autonomously in the future, relying on air conditioning to deal with the risk is a potentially maladaptive solution, and it expels waste heat into the environment – thereby enhancing the urban heat island effect.
  45. ^ Chen, Shau-Liang; Chang, Sih-Wei; Chen, Yen-Jen; Chen, Hsuen-Li (2021). "Possible warming effect of fine particulate matter in the atmosphere". Communications Earth & Environment. 2 (1): 208. Bibcode:2021ComEE...2..208C. doi:10.1038/s43247-021-00278-5. S2CID 238234137.
  46. ^ Wang, Tong; Wu, Yi; Shi, Lan; Hu, Xinhua; Chen, Min; Wu, Limin (2021). "A structural polymer for highly efficient all-day passive radiative cooling". Nature Communications. 12 (365): 365. doi:10.1038/s41467-020-20646-7. PMC 7809060. PMID 33446648.
  47. ^ Yoon, Siwon; Chae, Dongwoo; Seo, Junyong; Choi, Minwoo; Lim, Hangyu; Lee, Heon; Lee, Bong Jae (August 2022). "Development of a device for characterizing radiative cooling performance". Applied Thermal Engineering. 213: 118744. Bibcode:2022AppTE.21318744Y. doi:10.1016/j.applthermaleng.2022.118744. S2CID 249330437 – via Elsevier Science Direct.
  48. ^ a b c d e f Simsek, Eylul; Mandal, Jyotirmoy; Raman, Aaswath P.; Pilon, Laurent (December 2022). "Dropwise condensation reduces selectivity of sky-facing radiative cooling surfaces". International Journal of Heat and Mass Transfer. 198: 123399. Bibcode:2022IJHMT.19823399S. doi:10.1016/j.ijheatmasstransfer.2022.123399. S2CID 252242911.
  49. ^ a b c Zhou, Lyu; Rada, Jacob; Tian, Yanpei; Han, Yu; Lai, Zhiping; McCabe, Matthew F.; Gan, Qiaoqiang (September 2022). "Radiative cooling for energy sustainability: Materials, systems, and applications". Physical Review Materials. 6 (9): 090201. Bibcode:2022PhRvM...6i0201Z. doi:10.1103/PhysRevMaterials.6.090201. hdl:10754/681638. S2CID 252416825 – via APS Physics.
  50. ^ Lu, Zhengmao; Leroy, Arny; Zhang, Lenan; Patel, Jatin J.; Wang, Evelyn N.; Grossman, Jeffrey C. (September 2022). "Significantly enhanced sub-ambient passive cooling enabled by evaporation, radiation, and insulation". Cell Reports Physical Science. 3 (10): 101068. Bibcode:2022CRPS....301068L. doi:10.1016/j.xcrp.2022.101068. hdl:1721.1/146578. S2CID 252411940.
  51. ^ Ly, Kally Chein Sheng; Liu, Xianghui; Song, Xiaokun; Xiao, Chengyu; Wang, Pan; Zhou, Han; Fan, Tongxiang (May 2022). "A Dual-Mode Infrared Asymmetric Photonic Structure for All-Season Passive Radiative Cooling and Heating". Advanced Functional Materials. 32 (31). doi:10.1002/adfm.202203789. S2CID 248804080 – via Wiley.
  52. ^ a b Sarkar, Jahar; Bijarniya, Jay Prakash (December 2020). "Climate change effect on the cooling performance and assessment of passive daytime photonic radiative cooler in India". Renewable and Sustainable Energy Reviews. 134. Bibcode:2020RSERv.13410303B. doi:10.1016/j.rser.2020.110303 – via Elsevier Science Direct.
  53. ^ Li, Mengying; Peterson, Hannah B.; Coimbra, Carlos F. M. (2019). "Radiative cooling resource maps for the contiguous United States". Journal of Renewable and Sustainable Energy. 11 (3): 036501. doi:10.1063/1.5094510. S2CID 197617551.
  54. ^ Vilà, Roger; Medrano, Marc; Castell, Albert (2021). "Mapping Nighttime and All-Day Radiative Cooling Potential in Europe and the Influence of Solar Reflectivity". Atmosphere. 12 (9): 1119. Bibcode:2021Atmos..12.1119V. doi:10.3390/atmos12091119. ISSN 2073-4433.
  55. ^ a b c Weng, Yangziwan; Zhang, Weifeng; Jiang, Yi; Zhao, Weiyun; Deng, Yuan (September 2021). "Effective daytime radiative cooling via a template method based PDMS sponge emitter with synergistic thermo-optical activity". Solar Energy Materials and Solar Cells. 230: 111205. Bibcode:2021SEMSC.23011205W. doi:10.1016/j.solmat.2021.111205 – via Elsevier Science Direct.
  56. ^ Chen, Meijie; Pang, Dan; Yan, Hongjie (April 2022). "Sustainable and self-cleaning bilayer coatings for high-efficiency daytime radiative cooling". Journal of Materials Chemistry. 10 (2).
  57. ^ Carlosena, Laura; Andueza, Ángel; Torres, Luis; Irulegi, Olatz; Hernández-Minguillón, Rufino J.; Sevilla, Joaquín; Santamouris, Mattheos (2021). "Experimental development and testing of low-cost scalable radiative cooling materials for building applications". Solar Energy Materials and Solar Cells. 230: 111209. Bibcode:2021SEMSC.23011209C. doi:10.1016/j.solmat.2021.111209. hdl:10810/53717.
  58. ^ Huang, Xin; Mandal, Aaswath; Raman, Huang (November 2021). "Do-it-yourself radiative cooler as a radiative cooling standard and cooling component for device design". Photonics Energy. 12 (1). doi:10.1117/1.JPE.12.012112. S2CID 244383874.
  59. ^ a b Nie, Shijin; Tan, Xinyu; Li, Xinyi; Wei, Ke; Xiao, Ting; Jiang, Lihua; Geng, Jialing; Liu, Yuan; Hu, Weiwei; Chen, Xiaobo (November 2022). "Facile and environmentally-friendly fabrication of robust composite film with superhydrophobicity and radiative cooling property". Composites Science and Technology. 230 (1): 109750. doi:10.1016/j.compscitech.2022.109750. S2CID 252425283 – via Elsevier Science Direct.
  60. ^ a b c Wang, Tong; Zhang, Yinan; Chen, Min; Gu, Min; Wu, Limin (March 2022). "Scalable and waterborne titanium-dioxide-free thermochromic coatings for self-adaptive passive radiative cooling and heating". Cell Reports Physical Science. 3 (3): 100782. Bibcode:2022CRPS....300782W. doi:10.1016/j.xcrp.2022.100782. S2CID 247038918.
  61. ^ a b c Liu, Xianhu; Zhang, Mingtao; Hou, Yangzhe; Pan, Yamin; Liu, Chuntai; Shen, Changyu (September 2022). "Hierarchically Superhydrophobic Stereo-Complex Poly (Lactic Acid) Aerogel for Daytime Radiative Cooling". Advanced Functional Materials. 32 (46). doi:10.1002/adfm.202207414. S2CID 252076428 – via Wiley.
  62. ^ a b Fan, Ting-Ting; Xue, Chao-Hua; Guo, Xiao-Jing; Wang, Hui-Di; Huang, Meng-Chen; Zhang, Dong-Mei; Deng, Fu-Quan (May 2022). "Eco-friendly preparation of durable superhydrophobic porous film for daytime radiative cooling". Journal of Materials Science. 57 (22): 10425–10443. Bibcode:2022JMatS..5710425F. doi:10.1007/s10853-022-07292-8. S2CID 249020815 – via Springer.
  63. ^ a b c Zhong, Shenjie; Zhang, Jiawen; Yuan, Shuaixia; Xu, Tianqi; Zhang, Xun; Xu, Lang; Zuo, Tian; Cai, Ying; Yi, Lingmin (January 2023). "Self-assembling hierarchical flexible cellulose films assisted by electrostatic field for passive daytime radiative cooling". Chemical Engineering Journal. 451 (1): 138558. Bibcode:2023ChEnJ.45138558Z. doi:10.1016/j.cej.2022.138558. S2CID 251488725 – via Elsevier Science Direct.
  64. ^ a b Zhang, Yinan; Chen, Xi; Cai, Boyuan; Luan, Haitao; Zhang, Qiming; Gu, Min (2021). "Photonics Empowered Passive Radiative Cooling". Advanced Photonics Research. 2 (4). doi:10.1002/adpr.202000106. S2CID 233568826.
  65. ^ a b c Zhang, Haiwen; Ly, Kally C. S.; Liu, Xianghui; Chen, Zhihan; Yan, Max; Wu, Zilong; Wang, Xin; Zheng, Yuebeng; Zhou, Han; Fan, Tongxiang (2020). "Biologically inspired flexible photonic films for efficient passive radiative cooling". Proceedings of the National Academy of Sciences. 117 (26): 14657–14666. Bibcode:2020PNAS..11714657Z. doi:10.1073/pnas.2001802117. PMC 7334532. PMID 32541048.
  66. ^ a b c d e Mandal, Jyotirmoy; Yang, Yuan; Yu, Nanfung; Raman, Aaswath P. (July 2020). "Paints as a Scalable and Effective Radiative Cooling Technology for Buildings". Joule. 4 (7): 1350–1356. Bibcode:2020Joule...4.1350M. doi:10.1016/j.joule.2020.04.010. S2CID 219749984.
  67. ^ Levkin, Pavel A.; Svec, Frantisek; Fréchet, Jean M. J. (23 June 2009). "Porous Polymer Coatings: a Versatile Approach to Superhydrophobic Surfaces". Advanced Functional Materials. 19 (12): 1993–1998. doi:10.1002/adfm.200801916. ISSN 1616-301X. PMC 2760971. PMID 20160978.
  68. ^ "Cross-Linked Porous Polymeric Coating without a Metal-Reflective Layer for Sub-Ambient Radiative Cooling". doi:10.1021/acsami.0c14792.s001. Retrieved 21 November 2023.
  69. ^ Gao, Shilun; Li, Zhenxi; Liu, Nian; Liu, Guoliang; Yang, Huabin; Cao, Peng-Fei (August 2022). "Are Porous Polymers Practical to Protect Li-Metal Anodes? - Current Strategies and Future Opportunities". Advanced Functional Materials. 32 (31). doi:10.1002/adfm.202202013. ISSN 1616-301X. S2CID 249557441.
  70. ^ Atiganyanun, Sarun; Plumley, John B.; Han, Seok Jun; Hsu, Kevin; Cytrynbaum, Jacob; Peng, Thomas L.; Han, Sang M.; Han, Sang Eon (February 2018). "Effective Radiative Cooling by Paint-Format Microsphere-Based Photonic Random Media". ACS Photonics. 5 (4): 1181–1187. doi:10.1021/acsphotonics.7b01492 – via ACS Publications.
  71. ^ Li, Na; Wang, Junfeng; Liu, Defang; Huang, Xia; Xu, Zhikui; Zhang, Chenyang; Zhang, Zhijie; Zhong, Mingfeng (June 2019). "Selective spectral optical properties and structure of aluminum phosphate for daytime passive radiative cooling application". Solar Energy Materials and Solar Cells. 194: 103–110. Bibcode:2019SEMSC.194..103L. doi:10.1016/j.solmat.2019.01.036. S2CID 104321878 – via Elsevier Science Direct.
  72. ^ Li, Xiangyu; Peoples, Joseph; Yao, Peiyan; Ruan, Xiulin (April 2021). "Ultrawhite BaSO
    4
    Paints and Films for Remarkable Daytime Subambient Radiative Cooling"
    . ACS Applied Materials & Interfaces. 13 (18): 21733–21739. doi:10.1021/acsami.1c02368. PMID 33856776. S2CID 233259255 – via ACS Publications.
  73. ^ Zhou, Lei; Zhao, Jintao; Huang, Haoyun; Nan, Feng; Zhou, Guanghong; Qu, Qingdong (2021). "Flexible Polymer Photonic Films with Embedded Microvoids for High-Performance Passive Daytime Radiative Cooling". ACS Photonics. 8 (11): 3301–3307. doi:10.1021/acsphotonics.1c01149 – via ACS Publications.
  74. ^ a b Liaw, Wen-Chang; Chen, Chee-Shan; Chang, Wen-Shion; Chen, Kuan-Pin (February 2008). "Xylitol Production from Rice Straw Hemicellulose Hydrolyzate by Polyacrylic Hydrogel Thin Films with Immobilized Candida subtropicalis WF79". Journal of Bioscience and Bioengineering. 105 (2): 97–105. doi:10.1263/jbb.105.97. ISSN 1389-1723. PMID 18343334.
  75. ^ Zhang, Shuai; Jing, Weilong; Chen, Zhang; Zhang, Canying; Wu, Daxiong; Gao, Yanfeng; Zhu, Haitao (July 2022). "Full daytime sub-ambient radiative cooling film with high efficiency and low cost". Renewable Energy. 194: 850–857. Bibcode:2022REne..194..850Z. doi:10.1016/j.renene.2022.05.151. S2CID 249423146 – via Elsevier Science Direct.
  76. ^ a b c Wang, Ke; Luo, Guoling; Guo, Xiaowei; Li, Shaorong; Liu, Zhijun; Yang, Cheng (September 2021). "Radiative cooling of commercial silicon solar cells using a pyramid-textured PDMS film". Solar Energy. 225: 245. Bibcode:2021SoEn..225..245W. doi:10.1016/j.solener.2021.07.025 – via Elsevier Science Direct.
  77. ^ Tang, Huajie; Zhou, Zhihua; Jiao, Shifei; Zhang, Yunfei; Li, Shuai; Zhang, Debao; Zhang, Ji; Liu, Junwei; Zhao, Dongliang (January 2022). "Radiative cooling of solar cells with scalable and high-performance nanoporous anodic aluminum oxide". Solar Energy Materials and Solar Cells. 235: 111498. Bibcode:2022SEMSC.23511498T. doi:10.1016/j.solmat.2021.111498. S2CID 244299138.
  78. ^ a b c d Liu, Yanran; Zhang, Hanfang; Zhang, Yihe; Liang, Ce; An, Qi (July 2022). "Rendering passive radiative cooling capability to cotton textile by an alginate/CaCO
    3
    coating via synergistic light manipulation and high water permeation"
    . Composites Part B: Engineering. 240: 109988. doi:10.1016/j.compositesb.2022.109988. S2CID 249109763 – via Elsevier Science Direct.
  79. ^ a b Zeng, Shaoning; Pian, Sijie; Su, Minyu; Wang, Zhuning; Wu, Maoqi; Liu, Xinhang; Chen, Mingyue; Xiang, Yuanzhuo; Wu, Jiawei; Zhang, Manni; Cen, Qingqing; Tang, Yuwei; Zhou, Xianheng; Huang, Zhiheng; Wang, Rui (6 August 2021). "Hierarchical-morphology metafabric for scalable passive daytime radiative cooling". Science. 373 (6555): 692–696. Bibcode:2021Sci...373..692Z. doi:10.1126/science.abi5484. ISSN 0036-8075. PMID 34353954. S2CID 236929292.
  80. ^ Zhao, Guoxu; Wu, Tinglong; Wang, Ruhai; Li, Zhong; Yang, Qingzhen; Wang, Lei; Zhou, Hongwei; Jin, Birui; Liu, Hao; Fang, Yunsheng; Wang, Dong; Xu, Feng (20 October 2023). "Hydrogel-assisted microfluidic spinning of stretchable fibers via fluidic and interfacial self-adaptations". Science Advances. 9 (42): eadj5407. Bibcode:2023SciA....9J5407Z. doi:10.1126/sciadv.adj5407. ISSN 2375-2548. PMC 10588953. PMID 37862410.
  81. ^ Huang, Leping; Chen, Ying; Xu, Zhaobao; He, Cui; Li, Youmu; Zhao, Jinchao; Tang, Youhong (January 2023). "Regulating Al2O3/PAN/PEG Nanofiber Membranes with Suitable Phase Change Thermoregulation Features". Nanomaterials. 13 (16): 2313. doi:10.3390/nano13162313. ISSN 2079-4991. PMC 10457868. PMID 37630898.
  82. ^ a b Li, Yiping; An, Zhimin; Liu, Xinchao; Zhang, Rubing (October 2022). "A radiative cooling paper based on ceramic fiber for thermal management of human head". Solar Energy Materials and Solar Cells. 246: 111918. Bibcode:2022SEMSC.24611918L. doi:10.1016/j.solmat.2022.111918. S2CID 251335644 – via Elsevier Science Direct.
  83. ^ a b Li, Tao; Sun, Haoyang; Yang, Meng; Zhang, Chentao; Lv, Sha; Li, Bin; Chen, Longhao; Sun, Dazhi (2023). "All-Ceramic, Compressible and Scalable Nanofibrous Aerogels for Subambient Daytime Radiative Cooling". Chemical Engineering Journal. 452: 139518. Bibcode:2023ChEnJ.45239518L. doi:10.1016/j.cej.2022.139518. S2CID 252678873 – via Elsevier Science Direct.
  84. ^ Leroy, A.; Bhatia, B.; Kelsall, C.C.; Castillejo-Cuberos, A.M.; Capua H., Di; Zhang, L.; Guzman, A.M.; Wang, E.N. (October 2019). "High-performance subambient radiative cooling enabled by optically selective and thermally insulating polyethylene aerogel". Materials Science. 5 (10): eaat9480. Bibcode:2019SciA....5.9480L. doi:10.1126/sciadv.aat9480. PMC 6821464. PMID 31692957. S2CID 207896571.
  85. ^ Yue, Xuejie; Wu, Hai; Zhang, Tao; Yang, Dongya; Que, Fengxian (April 2022). "Superhydrophobic waste paper-based aerogel as a thermal insulating cooler for building". Energy. 245: 123287. Bibcode:2022Ene...24523287Y. doi:10.1016/j.energy.2022.123287. S2CID 246409163 – via Elsevier Science Direct.
  86. ^ Lee, Kang Won; Lim, Woojong; Jeon, Min Soo; Jang, Hanmin; Hwang, Jehwan; Lee, Chi Hwan; Kim, Dong Rip (2022). "Visibly Clear Radiative Cooling Metamaterials for Enhanced Thermal Management in Solar Cells and Windows". Advanced Functional Materials. 32 (1). doi:10.1002/adfm.202105882. S2CID 242578536 – via Wiley Online Library.
  87. ^ "Colorful films could help buildings, cars keep their cool". American Chemical Society. Retrieved 15 August 2024.
  88. ^ Zhao, Bin; Lu, Kegui; Hu, Mingke; Lu, Jie; Wu, Lijun; Xu, Chengfeng; Xuan, Qingdong; Pei, Gang (May 2022). "Radiative cooling of solar cells with micro-grating photonic cooler". Renewable Energy. 191: 662–668. Bibcode:2022REne..191..662Z. doi:10.1016/j.renene.2022.04.063. S2CID 248142250 – via Elsevier Science Direct.
  89. ^ a b Yang, Yuan; Zhang, Yifan (2020). "Passive daytime radiative cooling: Principle, application, and economic analysis". MRS Energy & Sustainability. 7 (18). doi:10.1557/mre.2020.18. S2CID 220008145. Archived from the original on 27 September 2022. Retrieved 27 September 2022.
  90. ^ a b c d e Mokharti, Reza; Ulpani, Giulia; Ghasempour, Roghayeh (July 2022). "The Cooling Station: Combining hydronic radiant cooling and daytime radiative cooling for urban shelters". Applied Thermal Engineering. 211. Bibcode:2022AppTE.21118493M. doi:10.1016/j.applthermaleng.2022.118493. S2CID 248076103 – via Elsevier Science Direct.
  91. ^ Feng, Chunzao; Yang, Peihua; Liu, Huidong; Mao, Mingran; Liu, Yipu; Xue, Tong; Fu, Jia; Cheng, Ting; Hu, Xuejiao; Fan, Hong Jin; Liu, Kang (July 2021). "Bilayer porous polymer for efficient passive building cooling". Nano Technology. 85. Bibcode:2021NEne...8505971F. doi:10.1016/j.nanoen.2021.105971. hdl:10356/155637 – via Elsevier Science Direct.
  92. ^ a b Zhou, Kai; Miljkovic, Nenad; Cai, Lili (March 2021). "Performance analysis on system-level integration and operation of daytime radiative cooling technology for air-conditioning in buildings". Energy and Buildings. 235: 110749. Bibcode:2021EneBu.23510749Z. doi:10.1016/j.enbuild.2021.110749. S2CID 234180182 – via Elsevier Science Direct.
  93. ^ Younes, Jaafar; Ghali, Kamel; Ghaddar, Nesreen (August 2022). "Diurnal Selective Radiative Cooling Impact in Mitigating Urban Heat Island Effect". Sustainable Cities and Society. 83: 103932. Bibcode:2022SusCS..8303932Y. doi:10.1016/j.scs.2022.103932. S2CID 248588547 – via Elsevier Science Direct.
  94. ^ Lu, Kegui; Zhao, Bin; Xu, Chengfeng; Li, Xiasheng; Pei, Gang (September 2022). "A full-spectrum synergetic management strategy for passive cooling of solar cells". Solar Energy Materials and Solar Cells. 245: 111860. Bibcode:2022SEMSC.24511860L. doi:10.1016/j.solmat.2022.111860. S2CID 250159405 – via Elsevier Science Direct.
  95. ^ Fang, Yunsheng; Chen, Guorui; Bick, Michael; Chen, Jun (July 2021). "Smart textiles for personalized thermoregulation". Chem. Soc. Rev. 50 (17): 9357–9374. doi:10.1039/D1CS00003A. PMID 34296235. S2CID 236198429 – via Royal Society of Chemistry.
  96. ^ Zeng, Shaoning (July 2021). "Hierarchical-morphology metafabric for scalable passive daytime radiative cooling". Science. 373 (6555): 692–696. Bibcode:2021Sci...373..692Z. doi:10.1126/science.abi5484. PMID 34353954. S2CID 236929292.
  97. ^ Cui, Chaofan; Lu, Jun; Zhang, Siqi; Su, Juanjuan; Han, Jian (October 2022). "Hierarchical-porous coating coupled with textile for passive daytime radiative cooling and self-cleaning". Solar Energy Materials and Solar Cells. 247: 111954. Bibcode:2022SEMSC.24711954C. doi:10.1016/j.solmat.2022.111954. S2CID 252097903 – via Elsevier Science Direct.
  98. ^ Li, Jinlei; Liang, Yuan; Li, Wei; Xu, Ning; Zhu, Bin; Wu, Zhen; Wang, Xueyang; Fan, Shanhui; Wang, Minghuai; Zhu, Jia (February 2022). "Protecting ice from melting under sunlight via radiative cooling". Science Advances. 8 (6): eabj9756. Bibcode:2022SciA....8.9756L. doi:10.1126/sciadv.abj9756. PMC 8836806. PMID 35148187.
  99. ^ Munday, Jeremy (2019). "Tackling Climate Change through Radiative Cooling". Joule. 3 (9): 2057–2060. Bibcode:2019Joule...3.2057M. doi:10.1016/j.joule.2019.07.010. S2CID 201590290.
  100. ^ Lin, Kaixin; Du, Yuwei; Chen, Siru; Chao, Luke; Lee, Hau Him; Ho, Tsz Chung; Zhu, Yihao; Zeng, Yijun; Pan, Aiqiang; Tso, Chi Yan (December 2022). "Nanoparticle-polymer hybrid dual-layer coating with broadband solar reflection for high-performance daytime passive radiative cooling". Energy and Buildings. 276: 112507. Bibcode:2022EneBu.27612507L. doi:10.1016/j.enbuild.2022.112507. S2CID 252510605 – via Elsevier Science Direct.
  101. ^ Wu, Wanchun; Lin, Shenghua; Wei, Mingming; Huang, Jinhua; Xu, Hua; Lu, Yuehui; Song, Weijie (June 2020). "Flexible passive radiative cooling inspired by Saharan silver ants". Solar Energy Materials and Solar Cells. 210: 110512. Bibcode:2020SEMSC.21010512W. doi:10.1016/j.solmat.2020.110512. S2CID 216200857 – via Elsevier Science Direct.
  102. ^ Kazemi, A.G.; Shirvani, A.H. (2011). "An Overview of Some Vernacular Techniques in Iranian Sustainable Architecture in Reference to Cisterns and Ice Houses". Journal of Sustainable Development. 4 (1). doi:10.5539/jsd.v4n1p264.
  103. ^ Irving, Michael (8 August 2024). "Nissan's new paint cools cars by up to 21 °F in direct sunlight". New Atlas. Retrieved 24 August 2024.