Nanoengineered Wool Textiles with Wrinkled Patterns for Enhanced Directional Radiative Cooling and Sun-Shade Effects

Applying zero-energy-input passive radiative cooling technology to personal thermal management systems can promote sustainable development and decrease energy consumption. However, the nearly horizontal internal radiation between cooling textiles and their surroundings hinders the transmission of thermal radiation into outer space, thereby diminishing the effectiveness of radiative cooling, because most of the wearable fabric on the human body is oriented vertically. Herein, we develop a nanoprocessed wool fabric with wrinkled patterns using a molecular bonding design strategy and scalable dip-coating methods to enhance solar spectrum reflection, followed by a thermal setting to form louver-like wrinkles. The wrinkled structures form a reflective surface oriented toward the direction of sunlight, which not only effectively reflects solar radiation directionally into outer space but also creates shaded areas to reduce the solar fluxes reaching the wearable fabric by around 50%. Nanoprocessed wrinkled wool fabric reflects over 90% of solar irradiance and selectively transmits human thermal radiation, allowing simulated skin to remain up to 10 °C cooler under direct sunlight and 2 °C cooler indoors compared to cotton fabrics. Moreover, the wool fabric retains its inherent breathability and comfort and excellent wear resistance. This efficient and scalable fabric design paves the way for sustainable energy solutions, smart textiles, and passive radiative cooling applications through the use of natural materials and geometrical structure engineering.