Optimizing retro-reflective surfaces to untrap radiation and cool cities

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Publication Date

March 11, 2024

Open Access

No

Abstract / Description

Extreme heat and its various impacts are a growing threat to cities and their residents, and it is increasingly clear that portfolios of solutions are needed to mitigate the resulting risks. Here we comprehensively evaluate and optimize the application of existing retro-reflective (RR) materials, which reflect incoming solar radiation back to the sky, on urban surfaces to cool them. Using detailed energy budget models, we show that RR walls and pavements decrease urban canyon surface temperatures by up to 20 °C and canyon air temperatures by up to 2.6 °C, outperforming highly reflective surfaces, with a notable improvement in pedestrian thermal comfort (up to 0.55 °C and 153 W m−2 reductions in human skin temperature and net radiative gain, respectively). We then develop optimized RR design guidelines for diverse climatic conditions, latitudes, seasons and urban geometries. On the basis of our analysis, we recommend RR pavements for open, low-rise areas and propose specific RR wall design strategies for compact, high-rise areas.

Authors

  • Xinjie Huang (Department of Civil and Environmental Engineering, Princeton University)
  • Elie Bou-Zeid (Department of Civil and Environmental Engineering, Princeton University)
  • Ilaria Pigliautile (CIRIAF – Interuniversity Research Center, University of Perugia, Department of Engineering, University of Perugia)

Additional Credits

Anna Laura Pisello (CIRIAF – Interuniversity Research Center, University of Perugia, Department of Engineering, University of Perugia), Jyotirmoy Mandal (Department of Civil and Environmental Engineering, Princeton University)

Publisher

Nature Cities

Suggested Citation

Huang, X., Bou-Zeid, E., Pigliautile, I. et al. Optimizing retro-reflective surfaces to untrap radiation and cool cities. Nat Cities 1, 275–285 (2024). https://doi.org/10.1038/s44284-024-00047-3