TY - GEN
T1 - Impact of Pavement Material Properties on Radiant Heat Exchanges with the Built Environment
AU - Arregi, Benat
AU - Lopez-Villamor, Inigo
AU - Zamora-Sanchez, Diego
AU - Garay-Martinez, Roberto
N1 - Publisher Copyright:
© 2025 University of Split, FESB.
PY - 2025
Y1 - 2025
N2 - There is a need for developing innovative pavement solutions for urban heat mitigation. This work presents the development of a model and a subsequent parametric study determining the impact of the material properties of pavements (thermal conductivity, heat capacity, solar absorptivity, infrared emissivity) over the surface temperatures of the ground and the boundary temperatures experienced by nearby buildings and people. The model explicitly considers dynamic heat storage effects, wind-dependent convective exchanges with the ambient, and the impact of solar and long-wave radiation exchanges. The parametric study compares the performance of a reference asphalt pavement to modifications (20% reduction) over each of its key material properties. Results indicate that the most relevant parameter is the solar absorptivity, followed by the emissivity. Changes in thermal conductivity or heat capacity have very limited effect. An interesting outcome is that reflective pavements with low solar absorption result in lower surface temperatures in the pavement, yet increased peak temperatures in neighbouring vertical surfaces (+2.5 °C) due to solar reflection and infrared radiative exchanges. In contrast, low-emissivity ground surfaces seem to achieve an opposite effect, increasing heat storage in the ground while reducing peak temperatures of nearby vertical surfaces (-1.2 °C).
AB - There is a need for developing innovative pavement solutions for urban heat mitigation. This work presents the development of a model and a subsequent parametric study determining the impact of the material properties of pavements (thermal conductivity, heat capacity, solar absorptivity, infrared emissivity) over the surface temperatures of the ground and the boundary temperatures experienced by nearby buildings and people. The model explicitly considers dynamic heat storage effects, wind-dependent convective exchanges with the ambient, and the impact of solar and long-wave radiation exchanges. The parametric study compares the performance of a reference asphalt pavement to modifications (20% reduction) over each of its key material properties. Results indicate that the most relevant parameter is the solar absorptivity, followed by the emissivity. Changes in thermal conductivity or heat capacity have very limited effect. An interesting outcome is that reflective pavements with low solar absorption result in lower surface temperatures in the pavement, yet increased peak temperatures in neighbouring vertical surfaces (+2.5 °C) due to solar reflection and infrared radiative exchanges. In contrast, low-emissivity ground surfaces seem to achieve an opposite effect, increasing heat storage in the ground while reducing peak temperatures of nearby vertical surfaces (-1.2 °C).
KW - ground
KW - heat transfer
KW - pavement
KW - transient model
KW - urban heat mitigation
UR - https://www.scopus.com/pages/publications/105013469555
U2 - 10.23919/SpliTech65624.2025.11091742
DO - 10.23919/SpliTech65624.2025.11091742
M3 - Conference contribution
AN - SCOPUS:105013469555
T3 - 2025 10th International Conference on Smart and Sustainable Technologies, SpliTech 2025
BT - 2025 10th International Conference on Smart and Sustainable Technologies, SpliTech 2025
A2 - Solic, Petar
A2 - Nizetic, Sandro
A2 - Rodrigues, Joel J. P. C.
A2 - Rodrigues, Joel J. P. C.
A2 - Rodrigues, Joel J.P.C.
A2 - Lopez-de-Ipina Gonzalez-de-Artaza, Diego
A2 - Perkovic, Toni
A2 - Vukojevic, Katarina
A2 - Catarinucci, Luca
A2 - Patrono, Luigi
PB - Institute of Electrical and Electronics Engineers Inc.
T2 - 10th International Conference on Smart and Sustainable Technologies, SpliTech 2025
Y2 - 16 June 2025 through 20 June 2025
ER -
