Ablimit Aili scite author profile

Reducing human reliance on energy-inefficient cooling methods such as air conditioning would have a large impact on the global energy landscape. By a process of complete delignification and densification of wood, we developed a structural material with a mechanical strength of 404.3 megapascals, more than eight times that of natural wood. The cellulose nanofibers in our engineered material backscatter solar radiation and emit strongly in mid-infrared wavelengths, resulting in continuous subambient cooling during both day and night. We model the potential impact of our cooling wood and find energy savings between 20 and 60%, which is most pronounced in hot and dry climates.

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Radiative sky cooling: Fundamental principles, materials, and applications

Zhao

et al. 2019

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Radiative sky cooling cools an object on the earth by emitting thermal infrared radiation to the cold universe through the atmospheric window (8–13 μm). It consumes no electricity and has great potential to be explored for cooling of buildings, vehicles, solar cells, and even thermal power plants. Radiative sky cooling has been explored in the past few decades but limited to nighttime use only. Very recently, owing to the progress in nanophotonics and metamaterials, daytime radiative sky cooling to achieve subambient temperatures under direct sunlight has been experimentally demonstrated. More excitingly, the manufacturing of the daytime radiative sky cooling material by the roll-to-roll process makes large-scale deployment of the technology possible. This work reviews the fundamental principles of radiative sky cooling as well as the recent advances, from both materials and systems point of view. Potential applications in different scenarios are reviewed with special attention to technology viability and benefits. As the energy situation and environmental issues become more and more severe in the 21st century, radiative sky cooling can be explored for energy saving in buildings and vehicles, mitigating the urban heat island effect, resolving water and environmental issues, achieving more efficient power generation, and even fighting against the global warming problem.

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Subambient Cooling of Water: Toward Real-World Applications of Daytime Radiative Cooling

Zhao

Aili

Zhai

et al. 2019

Joule

429

195

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Radiative sky cooling of large thermal mass water to 10.6 C below the ambient temperature is demonstrated around noon under direct sunlight by using polymerbased low-cost radiative cooling metamaterial. Subambient cool-water production at various constant temperatures is experimentally demonstrated. The parasitic effects of different weather conditions (local wind speed, precipitable water, and cloud cover) on the performance of sky radiative cooling have been investigated, which is critical for developing operation strategies for real-world applications.

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High-performance wearable thermoelectric generator with self-healing, recycling, and Lego-like reconfiguring capabilities

et al. 2021

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Thermoelectric generators (TEGs) are an excellent candidate for powering wearable electronics and the “Internet of Things,” due to their capability of directly converting heat to electrical energy. Here, we report a high-performance wearable TEG with superior stretchability, self-healability, recyclability, and Lego-like reconfigurability, by combining modular thermoelectric chips, dynamic covalent polyimine, and flowable liquid-metal electrical wiring in a mechanical architecture design of “soft motherboard-rigid plugin modules.” A record-high open-circuit voltage among flexible TEGs is achieved, reaching 1 V/cm2 at a temperature difference of 95 K. Furthermore, this TEG is integrated with a wavelength-selective metamaterial film on the cold side, leading to greatly improved device performance under solar irradiation, which is critically important for wearable energy harvesting during outdoor activities. The optimal properties and design concepts of TEGs reported here can pave the way for delivering the next-generation high-performance, adaptable, customizable, durable, economical, and eco-friendly energy-harvesting devices with wide applications.

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Selection of polymers with functional groups for daytime radiative cooling

Aili

Wei

Chen

et al. 2019

Materials Today Physics

151

101

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Ablimit Aili

A radiative cooling structural material

Radiative sky cooling: Fundamental principles, materials, and applications

Subambient Cooling of Water: Toward Real-World Applications of Daytime Radiative Cooling

High-performance wearable thermoelectric generator with self-healing, recycling, and Lego-like reconfiguring capabilities

Selection of polymers with functional groups for daytime radiative cooling

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