Retro-reflectors could help future cities keep their cool

By outfitting building walls and roadways in dense urban centers with retroreflective materials, Princeton Engineers found that it could be possible to reduce surface temperatures by up to 36°F, lower surrounding air temperatures by almost 5°F, and cool human skin temperatures by almost a degree Fahrenheit.

Colton Poore, Andlinger Center for Energy and the Environment

Engineers at Princeton University have quantified the cooling benefits of a simple solution for beating urban heat: reflecting solar radiation back from whence it came.

By outfitting building walls and roadways in dense urban centers with retroreflective materials, which reflect most incoming light directly back to its source, the researchers found that it could be possible to reduce surface temperatures by up to 36°F, lower surrounding air temperatures by almost 5°F, and cool human skin temperatures by almost a degree Fahrenheit.

Such retroreflective surfaces could be a key strategy for fending off urban heat in dense, high-rise cities like New York, Hong Kong, and Singapore. Working with collaborators from the University of Perugia in Italy, the team published their findings, including guidelines for installing retroreflective surfaces in cities around the globe, on March 11 in Nature Cities.

“More people die from extreme heat in the U.S. than from any other weather-related event — heat kills more than tornadoes, tsunamis, and hurricanes combined,” said corresponding author Elie Bou-Zeid, professor of civil and environmental engineering. “And with climate change being linked to more frequent and long-lasting extreme heat events, there’s an urgent need to develop and deploy technologies that can help people stay cool.”

Owing to a lack of green spaces and an abundance of heat-trapping building materials, urban areas are often several degrees warmer than surrounding suburban and rural areas — a phenomenon known as the urban heat island effect. This makes people living in cities, including some of society’s most vulnerable populations, particularly susceptible to the impacts of extreme heat.

Several technologies have been proposed to combat the issue of urban overheating, including cool pavements and roof coatings. These approaches can be as simple as painting the ground or rooftop in a shade of white to increase the amount of sunlight reflected from, rather than absorbed by, a city’s built environment. In Phoenix, Arizona, for instance, cool pavement treatments have become a permanent part of the city’s street maintenance program.

However, when sunlight hits these cooling technologies, it can bounce off in any number of angles instead of in one focused direction. This lack of control over the direction of the reflected light means that highly reflective materials could backfire if applied to the streets or walls of a dense urban area with tall buildings and comparatively narrow streets.

“Installing highly reflective technologies on building walls could be a serious problem, with respect to both the heat and general safety,” said Bou-Zeid. “Those photons might be reflected out of the urban canyon, or they could be reflected onto the ground, onto other walls, and even onto the pedestrians themselves.”

Unlike generic highly reflective materials, retroreflectors can reflect incoming sunlight with limited scattering. Consequently, most sunlight hitting a retroreflector on a building wall or city street would be directed back in the same direction it came from — and out of the urban canyon.

“In this way, the retroreflectors can release the radiation that would otherwise be stuck in the urban canyon and exacerbate the urban overheating problem,” said first author Xinjie Huang, a graduate student in civil and environmental engineering.

Retroreflective stickers.
Retroreflective materials are already commonplace in the transportation sector, but the researchers found that a similar technology could also help to combat urban heat (photo from adobe.stock.com).

Retroreflective materials are already used in the transportation sector, where they are commonly found in road signs and paint to enhance nighttime visibility. Other research groups at Princeton are even using retroreflectors to help them pinpoint greenhouse gas leaks. But using retroreflectors for cooling purposes in façade applications is still an evolving area of research.

“There are retroreflectors on the market today, but an important question is how efficient we can make them and whether we can engineer them to have the properties we want,” said co-author Jyotirmoy Mandal, assistant professor of civil and environmental engineering. “Insights from optics and materials science allow us to choose the right materials and make the right design tweaks to push the performance of these technologies to their limit.”

The present work did not focus on the materials science question of how to engineer the best retroreflector for urban cooling. However, the researchers said their work is among the first to evaluate the potential cooling benefits of the technology at a global scale, moving beyond individual case studies to offer practical insights into how best to implement retroreflective surfaces in cities around the world.

“Ultimately, we wanted to create a set of guidelines for policymakers, planners, and materials engineers,” Huang said. “If you’re an urban planner, for example, and you know the latitude of your city, the aspect ratio and the orientation of your streets, you can easily use our results to pick the optimal surfaces for implementing these retroreflective materials and estimate the cooling benefits you might receive in doing so.”

The paper, “Optimizing retro-reflective surfaces to untrap radiation and cool cities,” was published March 11 in Nature Cities. In addition to Bou-Zeid, Huang, and Mandal, co-authors include Illaria Pigliautile and Anna Laura Pisello from the University of Perugia, Italy.

The research was supported by Princeton University’s School of Engineering Innovation Funds and the Dean for Research Innovation Fund for Exploratory Energy Research. Additionally, the authors acknowledge support from the European Research Council and the Italian funding program National Operational Programme on Research and Innovation 2014-2020.