Photonic design for color compatible radiative cooling accelerated by materials informatics

TL;DR: In this paper , a daytime radiative cooling emitter (DRCE) consisting of polydimethylsiloxane, silicon dioxide, and aluminum nitride from top to bottom on a silver-silicon substrate was designed by a machine learning method (MLM) and genetic algorithm.

TL;DR: Researchers design a dual-mode thermal management film with high-purity color display, achieving 92.1% solar reflectivity and 96.0% infrared emissivity for cooling, and 61.5% solar absorption and 8.2% infrared emissivity for heating, reducing energy consumption by 10.3%.

TL;DR: Bi-rhombic radiative cooling metamaterial exhibits high emissivity in the atmospheric window and achieves efficient cooling and continuous power generation.

TL;DR: This review paper introduces Bayesian optimization, highlights some of its methodological aspects, and showcases a wide range of applications.

TL;DR: An integrated photonic solar reflector and thermal emitter consisting of seven layers of HfO2 and SiO2 that reflects 97 per cent of incident sunlight while emitting strongly and selectively in the atmospheric transparency window demonstrates that the cold darkness of the Universe can be used as a renewable thermodynamic resource, even during the hottest hours of the day.

TL;DR: This work analyzes GP-UCB, an intuitive upper-confidence based algorithm, and bound its cumulative regret in terms of maximal information gain, establishing a novel connection between GP optimization and experimental design and obtaining explicit sublinear regret bounds for many commonly used covariance functions.

TL;DR: A metamaterial composed of a polymer layer embedded with microspheres, backed with a thin layer of silver, which shows a noontime radiative cooling power of 93 watts per square meter under direct sunshine is constructed.