Artificially adjustable radiative cooling device with environmental adaptability

Abstract

In recent years, radiative cooling has garnered widespread attention due to its energy-independent and environmentally friendly nature. However, one major challenge in the field of radiative cooling faces is the lack of artificial control over the cooling effect, which not only impacts cooling comfort but also leads to unnecessary energy waste during heating in cold environments. In this paper, a novel approach to address this challenge is proposed by a radiative cooling device with a three-layer structure consisting of vanadium dioxide (VO2), polydimethylsiloxane (PDMS) and silver. The transition of VO2 between the metallic and insulating states results in the formation and disappearance of the Fabry-Pérot resonator, thereby facilitating the transition between different cooling modes. Additionally, the stretchability of the PDMS enables the device to achieve different radiative cooling power by applying varying levels of stress. In high-temperature environments, it achieves an average net radiative cooling power of 96.2 W/m2 throughout the day, highlighting its exceptional energy-saving capabilities. In low-temperature environments, the cooling effect can be suppressed to prevent excessive cooling, achieving a temperature reduction as low as 0.4 °C. This device offers controllable cooling power, and its diverse control modes in different environments contribute to its excellent environmental adaptability.