A Modern Roman-Inspired Concrete with Daytime Radiative Cooling Capacity

Jorge S. Dolado; Guido Goracci; Ghizlane Moutaoukil; Ridwan O. Agbaoye; Miguel Beruete; Alicia E. Torres-García; Laura Carlosena; Achutha Prabhu; Jose A. Ibáñez; Nick Adams; Nicole van Lipzig; Karen Allacker

doi:10.1002/advs.202511691

A Modern Roman-Inspired Concrete with Daytime Radiative Cooling Capacity

Jorge S. Dolado^*
, Guido Goracci
, Ghizlane Moutaoukil
, Ridwan O. Agbaoye
, Miguel Beruete
, Alicia E. Torres-García
, Laura Carlosena
, Achutha Prabhu
, Jose A. Ibáñez
, Nick Adams
, Nicole van Lipzig
, Karen Allacker

^*Autor correspondiente de este trabajo

Producción científica: Contribución a una revista › Artículo › revisión exhaustiva

2 Citas (Scopus)

11 Descargas (Pure)

Resumen

Addressing global warming through the modernization of buildings and urban areas is a major challenge. Passive daytime radiative cooling (PDRC) materials offer potential solutions, but none have effectively replaced concrete's dominant role in urban environments. Here, a Roman-inspired concrete with PDRC capabilities is presented, combining high solar reflectance (≈0.95) and long-wave infrared (LWIR) emittance (≈0.91). It delivers cooling powers over 45 W m⁻² under average solar intensities of 850 W m⁻² without a convection shield. On hot days (above 30°C), it stays 2°C cooler than the surrounding air under solar irradiance up to 985 W m⁻². Simulations predict this concrete can reduce energy use and CO₂ emissions by ≈50% in hot regions and lower urban surface temperatures by up to 10°C during heat waves. This breakthrough offers a cheap, scalable and sustainable solution for energy efficiency and climate resilience.

Idioma original	Inglés
Número de artículo	e11691
Publicación	Advanced Science
Volumen	12
N.º	47
DOI	https://doi.org/10.1002/advs.202511691
Estado	Publicada - 18 dic 2025

ODS de las Naciones Unidas

Este resultado contribuye a los siguientes Objetivos de Desarrollo Sostenible

ODS 7: Energía asequible y no contaminante
ODS 11: Ciudades y comunidades sostenibles
ODS 12: Producción y consumo responsables
ODS 13: Acción por el clima

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10.1002/advs.202511691

Advanced Science - 2025 - Dolado - A Modern Roman‐Inspired Concrete with Daytime Radiative Cooling CapacityVersión publicada final, 4,45 MBLicencia: CC BY

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title = "A Modern Roman-Inspired Concrete with Daytime Radiative Cooling Capacity",

abstract = "Addressing global warming through the modernization of buildings and urban areas is a major challenge. Passive daytime radiative cooling (PDRC) materials offer potential solutions, but none have effectively replaced concrete's dominant role in urban environments. Here, a Roman-inspired concrete with PDRC capabilities is presented, combining high solar reflectance (≈0.95) and long-wave infrared (LWIR) emittance (≈0.91). It delivers cooling powers over 45 W m−2 under average solar intensities of 850 W m−2 without a convection shield. On hot days (above 30°C), it stays 2°C cooler than the surrounding air under solar irradiance up to 985 W m−2. Simulations predict this concrete can reduce energy use and CO2 emissions by ≈50\% in hot regions and lower urban surface temperatures by up to 10°C during heat waves. This breakthrough offers a cheap, scalable and sustainable solution for energy efficiency and climate resilience.",

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AU - Dolado, Jorge S.

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AU - Agbaoye, Ridwan O.

AU - Beruete, Miguel

AU - Torres-García, Alicia E.

AU - Carlosena, Laura

AU - Prabhu, Achutha

AU - Ibáñez, Jose A.

AU - Adams, Nick

AU - van Lipzig, Nicole

AU - Allacker, Karen

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AB - Addressing global warming through the modernization of buildings and urban areas is a major challenge. Passive daytime radiative cooling (PDRC) materials offer potential solutions, but none have effectively replaced concrete's dominant role in urban environments. Here, a Roman-inspired concrete with PDRC capabilities is presented, combining high solar reflectance (≈0.95) and long-wave infrared (LWIR) emittance (≈0.91). It delivers cooling powers over 45 W m−2 under average solar intensities of 850 W m−2 without a convection shield. On hot days (above 30°C), it stays 2°C cooler than the surrounding air under solar irradiance up to 985 W m−2. Simulations predict this concrete can reduce energy use and CO2 emissions by ≈50% in hot regions and lower urban surface temperatures by up to 10°C during heat waves. This breakthrough offers a cheap, scalable and sustainable solution for energy efficiency and climate resilience.

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KW - global warming

KW - radiative cooling technology

KW - urban heat island effect

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ER -

A Modern Roman-Inspired Concrete with Daytime Radiative Cooling Capacity

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