A Janus Smart Window for Temperature-Adaptive Radiative Cooling and Adjustable Solar Transmittance
Zuowei Zhang, Meina Yu, Cong Ma, Longxiang He, Xian He, Baohua Yuan, Luoning Zhang, Cheng Zou, Yanzi Gao, Huai Yang
Abstract
Abstract The advancement of sophisticated smart windows exhibiting superior thermoregulation capabilities in both solar spectrum and long-wave infrared range maintains a prominent objective for researchers in this field. In this study, a Janus window is proposed and prepared based on polymer-stabilized liquid–crystal films/thermochromic materials. It can achieve switchable front long-wave infrared emissivity ( ε Front ) and solar modulation ability (Δ T sol ) through dynamic flipping, making it suitable for different seasonal energy-saving requirements. Outdoor experiments show that under daytime illumination, the indoor temperature decreases by 8 °C, and the nighttime temperature drops by 5 °C. MATLAB simulation calculations indicate that the daytime cooling power is 93 W m −2 , while the nighttime cooling power reaches 142 W m −2 . Interestingly, by modifying the conductive layer, it can effectively shield electromagnetic radiation (within the X-band frequency range (8.2–12.4) GHz). Energy simulation reveals the substantial superiority of this device in energy savings compared with single-layer polymer-stabilized liquid crystal, poly(N-isopropyl acrylamide), and normal glass when applied in different climate zones. This research presents a compelling opportunity for the development of sophisticated smart windows characterized by exceptional thermoregulation capabilities.