Radiative cooling to deep sub-freezing temperatures through a 24-h day–night cycle

Chen, Zhe; Zhu, Linxiao; Raman, Aaswath; Fan, Shanhui

doi:10.1038/ncomms13729

Cited by 678 publications

(454 citation statements)

References 24 publications

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“…According to (5), solar absorption and non-radiative heat transfer act as parasitic cooling losses, thereby reducing the overall cooling efficiency and increasing the cooling time to reach thermal equilibrium. Remarkably, it has been experimentally demonstrated that significant temperature reduction up to 40 K below ambient has been reached by radiative cooling within 1 h [47]. For systems with greater heat loads (e.g.…”

Section: Principle Of Coolingmentioning

confidence: 99%

Radiative sky cooling: fundamental physics, materials, structures, and applications

et al. 2017

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Radiative sky cooling reduces the temperature of a system by promoting heat exchange with the sky; its key advantage is that no input energy is required. We will review the origins of radiative sky cooling from ancient times to the modern day, and illustrate how the fundamental physics of radiative cooling calls for a combination of properties that may not occur in bulk materials. A detailed comparison with recent modeling and experiments on nanophotonic structures will then illustrate the advantages of this recently emerging approach. Potential applications of these radiative cooling materials to a variety of temperature-sensitive optoelectronic devices, such as photovoltaics, thermophotovoltaics, rectennas, and infrared detectors, will then be discussed. This review will conclude by forecasting the prospects for the field as a whole in both terrestrial and space-based systems.

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Section: Principle Of Coolingmentioning

confidence: 99%

Radiative sky cooling: fundamental physics, materials, structures, and applications

et al. 2017

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“…25 Achieving such low temperatures requires high vacuum to minimize parasitic conduction and convection. 21 If such parasitic mechanisms are present, expanding the bandwidth of thermal emission is likely to be benecial despite the increase in sky radiation absorption as shown in Figure 4b.…”

Section: Acs Photonicsmentioning

confidence: 99%

“…Thus, expanding the spectral range of high emissivity can be benecial under some circumstances. 21,25 For a cooler temperature of 300 K, Case 1 achieves a cooling power density 158 Wm -2 , 43 Wm -2 higher than Case 2.…”

Section: Acs Photonicsmentioning

confidence: 99%

“…Subsequently, Chen et al was able to demonstrate an average temperature reduction of 37 • C below ambient by combining a selective emitter with an apparatus consisting of a vacuum chamber. 21 Related to these experiments, there have been other recent theoretical works in designing various photonic structures for radiative cooling purposes. 12,2225 Most of these radiative coolers are designed to emit only in the atmospheric transparency window to avoid exchanging radiation with the atmosphere.…”

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confidence: 99%

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Daytime Radiative Cooling Using Near-Black Infrared Emitters

et al. 2017

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Recent works have demonstrated that daytime radiative cooling under direct sunlight can be achieved using multilayer thin films designed to emit in the infrared atmospheric transparency window while reflecting visible light. Here, we demonstrate that a polymer-coated fused silica mirror, as a near-ideal blackbody in the mid-infrared and near-ideal reflector in the solar spectrum, achieves radiative cooling below ambient air temperature under direct sunlight (8.2 °C) and at night (8.4 °C). Its performance exceeds that of a multilayer thin film stack fabricated using vacuum deposition methods by nearly 3 °C. Furthermore, we estimate the cooler has an average net cooling power of about 127 W m–2 during daytime at ambient temperature even considering the significant influence of external conduction and convection, more than twice that reported previously. Our work demonstrates that abundant materials and straightforward fabrication can be used to achieve daytime radiative cooling, advancing applications such as dry cooling of thermal power plants.

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“…On the basis of global water cycle, moderate global temperature, humidity, and precipitation may be attainable through the tunable plant transpiration. Moreover, photothermal conversion shows the potential as the regulator of the nature, besides the emerging applications, such as radiative cooling,42, 43, 44, 45 thermophotovoltaics,46, 47, 48, 49 water purification,10, 11, 12, 13, 14, 15, 16, 17, 18, 19, 20, 21, 22, 23 seawater desalination,24, 25, 26, 27 and power generation 28, 29…”

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confidence: 99%

Tuning Transpiration by Interfacial Solar Absorber‐Leaf Engineering

Zhuang

Lin

et al. 2017

Advanced Science

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Plant transpiration, a process of water movement through a plant and its evaporation from aerial parts especially leaves, consumes a large component of the total continental precipitation (≈48%) and significantly influences global water distribution and climate. To date, various chemical and/or biological explorations have been made to tune the transpiration but with uncertain environmental risks. In recent years, interfacial solar steam/vapor generation is attracting a lot of attention for achieving high energy transfer efficiency. Various optical and thermal designs at the solar absorber–water interface for potential applications in water purification, seawater desalination, and power generation appear. In this work, the concept of interfacial solar vapor generation is extended to tunable plant transpiration by showing for the first time that the transpiration efficiency can also be enhanced or suppressed through engineering the solar absorber–leaf interface. By tuning the solar absorption of membrane in direct touch with green leaf, surface temperature of green leaf will change accordingly because of photothermal effect, thus the transpiration efficiency as well as temperature and relative humidity in the surrounding environment will be tuned. This tunable transpiration by interfacial absorber‐leaf engineering can open an alternative avenue to regulate local atmospheric temperature, humidity, and eventually hydrologic cycle.

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Radiative cooling to deep sub-freezing temperatures through a 24-h day–night cycle

Cited by 678 publications

References 24 publications

Radiative sky cooling: fundamental physics, materials, structures, and applications

Radiative sky cooling: fundamental physics, materials, structures, and applications

Daytime Radiative Cooling Using Near-Black Infrared Emitters

Tuning Transpiration by Interfacial Solar Absorber‐Leaf Engineering

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