Towards cooling concrete: Evaluation of cement and cement composites under realistic climatic conditions
Alicia E. Torres‐García, Ridwan O. Agbaoye, Laura Carlosena, G Goracci, Carlos Lezaun, Jorge S. Dolado, Miguel Beruete
Abstract
• Achieving passive daytime radiative cooling using cement-based compounds. • Effective cooling using portlandite and tobermorite without external additives. • Cooling comparison of portlandite and tobermorite with other cements. • Significant indoor temperature reduction, with CH outperforming other cements. • Cooling performance under varying climatic conditions for global application. Finding scalable, cost-effective and environmentally safe solutions for Passive Daytime Radiative Cooling (PDRC) is essential for addressing energy and climate challenges. This study demonstrates the feasibility of achieving PDRC using only cement-based compounds, without the need for additional whitening agents or other additives. Unlike previous approaches that rely on external additives, the proposed solution leverages two fundamental cement phases—portlandite and tobermorite—offering a scalable and low-impact alternative. The research evaluates the radiative cooling potential of these phases, along with two widely used cements—white cement (WC) and ordinary Portland cement (OPC), by analyzing and comparing their homogenized complex permittivities, derived using the Kramers-Kronig (KK) method. Simulations were conducted to assess the cooling power over one year across three different climates using actual meteorological data. The portlandite exhibits positive Pcool, maintaining a temperature equal to or below the ambient temperature more than 90 % of the time in dry desert and warm temperate locations. Indoor controlled measurements results reveal that portlandite (CH) may exhibit temperatures 15 °C lower than OPC and 5 °C lower than WC.