Efficient radiative cooling coating with biomimetic human skin wrinkle structure

Daytime radiative cooling is an energy-free pathway to achieve cooling performance. Current radiative cooling materials with periodic photonic structures are facing a huge challenge in terms of scale expansion owing to complex preparation technology and high cost. Herein, we proposed the idea of using biomimetic wrinkle structure combined with optimized particles to achieve the efficient optical property regulation of both the solar band and "atmospheric window" band. On this basis, a large-scale radiative cooling coating with the biomimetic structure of human skin natural wrinkle, comprising high concentrations of BaSO4 and SiO2 particles, was demonstrated. The coating with a thickness of similar to 100 mu m reflected similar to 95% of solar irradiance, and the emissivity in the "atmospheric window" band was similar to 96%. At noontime (11:00-13:00), in a populous area located at sea level, the average effective cooling power of similar to 89.6 W/m(2) was recorded, and the maximum sub-ambient temperature drop can reach 8.1 degrees C. An outdoor-building test conducted over a year showed that the maximum average indoor air temperature of the building painted with the coating was reduced by 6.2 degrees C and the maximum power-saving rate of air-conditioning exceeded 50%. Our work provided a new idea for designing, fabrication, and application of high-performance radiative cooling materials.