辐射冷却
材料科学
发射率
保温
硅酸盐水泥
聚合物
被动冷却
辐射传输
高效能源利用
环境科学
工艺工程
余热
生命周期评估
热导率
能源消耗
水泥
温室气体
热的
废物管理
节能
电
太阳能
自由冷却
辐射冷却
发电
热能
暖通空调
热能储存
冷负荷
能量(信号处理)
碳纤维
热发射率
冷却能力
热效率
火力发电站
空调
热舒适性
环境友好型
建筑材料
储能
作者
Yifan Zhou,J Liu,Hailu Wei,Yan Liang,Weiyi Zhang,Yahui Du,Junying Lai,Jinyue Yan
标识
DOI:10.1021/acsami.6c00679
摘要
The construction industry, driven by the growing energy demands for heating, cooling, and lighting, accounts for nearly 40% of global energy consumption. It heavily relies on traditional materials such as Ordinary Portland Cement (OPC), whose production is energy-intensive and accounts for approximately 8% of global carbon dioxide (CO2) emissions. This study presents a multifunctional radiative cooling geopolymer (MRCG) as a promising and sustainable building material designed to address the aforementioned challenges. Prepared via an environmentally benign process, MRCG integrates thermal insulation and radiative cooling within a single material matrix. It exhibits a low thermal conductivity of 0.31 W/(m·K), significantly lower than that of conventional cement (1.13 W/(m·K)), while maintaining fire resistance and high compressive strength, supporting durable implementation in practical building applications. Meanwhile, MRCG delivers strong optical performance, with solar reflectance exceeding 93% and mid-infrared emissivity above 95%, enabling daytime subambient cooling of approximately 4.0 °C. Such cooling capability is expected to reduce HVAC electricity demand and thereby lower operational CO2 emissions in buildings. The modeling results demonstrate energy savings of up to 23% in hot climates when using MRCG, underscoring its regional adaptability and environmental benefits. By combining low thermal conductivity, high strength, and effective radiative cooling, MRCG provides a promising solution for future energy-efficient buildings, contributing to global carbon reduction goals.
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