辐射冷却
电子设备和系统的热管理
热的
辐射传输
核工程
太阳能
工程物理
环境科学
热辐射
材料科学
能源管理
工艺工程
能量(信号处理)
物理
热力学
光学
机械工程
工程类
电气工程
量子力学
作者
Ruiming Tan,Yinyan Li,Gongxun Bai,Cuilu Xi,Peng Xue,Yuxin Ma,Beibei Xu,Shiqing Xu,Jianhua Hao
标识
DOI:10.1021/acssuschemeng.4c10372
摘要
The application of zero-emission passive radiative coolers is a crucial step toward global carbon neutrality. However, a single radiative cooling function cannot meet the thermal requirements under various weather conditions. We present a dual-mode thermal management film that integrates passive radiative cooling and heating functions through its porous polymer surface for cooling and a light-to-heat conversion surface enabled by graphene and carbon nanotubes for heating. The surfaces of the dual-mode film were physically flipped, positioning the corresponding surface toward solar radiation to obtain the desired functionality. In the cooling surface, the film achieves sub-ambient cooling of ≈13.3 °C under 853.88 W m–2 of sunlight, thanks to its high solar reflectance (0.92) and mid-infrared emissivity (0.95). In the heating surface, it uses high solar absorption (0.90) to increase the temperature by 11.4 °C and generates Joule heating at various voltage levels. According to EnergyPlus software estimates, buildings with roofs covered in the film could reduce CO2 emissions by 1.109 billion metric tons, equivalent to 3% of current global CO2 emissions. This study offers a promising solution to climate challenges and holds great potential for energy savings and carbon reduction.
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