材料科学
辐射冷却
发射率
辐射传输
胶凝的
热光电伏打
带隙
光电子学
水泥
复合材料
工作(物理)
热的
光子学
电介质
低发射率
纳米复合材料
红外线的
热辐射
保温
各向异性
光学
拉曼散射
光子晶体
反射率
辐射能
电子能带结构
氧化物
作者
Jozef Janovec,Guido Goracci,J. J. Dolado,Andrés Ayuela
出处
期刊:Energy & environmental materials
[Wiley]
日期:2026-01-08
被引量:1
摘要
This work evaluates the radiative cooling potential of cement as a component of photonic metaconcrete, capable of energy savings and reduction of CO 2 emissions. In particular, we present a comparative study of the optical and radiative properties of primary clinker products (alite and belite) and typical sulfate additives (CaSO 4 and gypsum) across the ultraviolet, visible, and infrared ranges. The dielectric response, emissivity, and reflectance were obtained using first‐principle calculations, specifically density functional theory, together with the GW and the Bethe–Salpeter equation methods. This advanced computational approach identified strongly anisotropic excitons within the electronic band gaps of the cement phases. Our findings revealed that both oxygen–silicon and oxygen–sulfur bonds play a central role in thermal emission within the atmospheric transparency window. The combination of selective emissivity and high solar reflectivity suggests that cement‐based nanocomposites are promising materials for radiative cooling applications. Furthermore, the reflectance measurements indicate an optical band gap of approximately 5.24 eV for alite. Overall, this work advances the understanding of the optical and thermal behavior of cementitious materials and provides insights into the design of energy‐efficient photonic concrete composites.
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