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Glow-in-the-dark materials can help cities stay cooler and use less electricity — here’s how they work

Luminescent substances, like glowing paint, can be an energy-efficient way to light bike lanes, road markers, sidewalks, and even buildings. ...

Cars race down Austin's Sixth Street at night
If a path was painted with paint that glows all night, light energy would decrease by 27%, a simulation report showed.

  • Luminescent materials are used for emergency lighting and street markings around the world.
  • They help keep cities cool by re-emitting light that would otherwise be converted into heat. 
  • As these glow-in-the-dark materials are improved, they can be used for more energy efficient cities. 

Around the year 1603, Italian shoemaker and amateur alchemist Vincenzo Casserole tried smelting some especially dense stone he had found on the slopes of Mount Paderno, near Bologna. No gold, silver, or other precious metals resulted as he had hoped. But after the stone had cooled, Casciarolo discovered something interesting: If he exposed the material to sunlight and then took it into a dark room, the stone would glow.

That "Bologna Stone" was the first artificially prepared, persistently luminescent substance. Many more were to follow — and today, persistent luminescent materials are used for decorations, emergency lighting, pavement markings, and medical imaging.

Someday they might give us glowing cities that stay cooler and use less electricity. 

new generation of luminescent materials has the potential to cool cities by re-emitting light that would otherwise be converted into heat. They might also cut down on energy use, since luminescent sidewalks, glowing road markers, or even glowing buildings could replace some street lighting. Already, some cities in Europe have installed glowing bicycle lanes, and some researchers have studied using glowing paint for road markings.

"It's better for the environment," said Paul Berdahl, an environmental physicist now retired from Lawrence Berkeley National Laboratory in Berkeley, California. "If the technology can be improved, we can use less energy.… It's a worthwhile thing to do."

The Bologna Stone, a form of the mineral baryte, fascinated natural philosophers at the time, but was never especially useful. But in the 1990s, chemists developed new types of persistent photoluminescent materials, such as strontium aluminate, that maintained a strong glow for hours after exposure to light. Most of these new materials give off a blue or green glow, although a few glow yellow, red, or orange.

Such photoluminescent materials work by "trapping" the energy of a photon and then re-emitting that energy as lower-wavelength light. Sometimes the light is emitted immediately, such as in a fluorescent light bulb. Other materials, which are called persistently luminescent, store the energy longer and emit it more slowly.

More than 250 kinds of luminescent materials have been identified. Above they are grouped by a) the trace materials that act as the luminescent center; b) the host compound; and c) the color the material emits.
More than 250 kinds of luminescent materials have been identified. Above they are grouped by a) the trace materials that act as the luminescent center; b) the host compound; and c) the color the material emits.

These materials that glow strongly for hours open possibilities, such as "glow-in-the-dark" cities lighted by luminescent pavements and buildings. Since 19% of all global energy use is for lighting, and in Europe about 1.6% specifically for street lighting, the potential energy savings are large, write building engineer Anna Laura Pisello and colleagues in the 2021 "Annual Review of Materials Research."

One problem with the approach is that most luminescent material won't glow all the way through the night. Better materials could help solve that problem, says Pisello, of the University of Perugia, who studies energy-efficient building materials. In the meantime, existing materials could be combined with electric lighting that would come on long enough to recharge the road markings before switching off again.

Luminescent paint could also provide outdoor area lighting. Pisello's lab developed such a glow-in-the-dark paint and in a 2019 report, simulated what would happen if they painted a public path near a railway station with it. By glowing throughout the night, the paint would reduce energy needed for lighting by about 27% in the immediate area, the scientists found.

If this conjures worries of entire cities glaring throughout the night and adding to harmful light pollution, Pisello says that is unlikely. Luminescent materials would likely only replace existing lighting, not add to it. The color of the glowing materials could be chosen to avoid the blue frequencies that have been found especially harmful to wildlife.

Luminescent materials could also help fight what is known as the urban heat island effect. Rooftops and pavements absorb energy from the sun and emit it as heat, driving city summer temperatures an average of 7.7° C higher than in the surrounding countryside. The high temperatures are a potential health hazard and also result in more energy being used to cool buildings.

One increasingly common solution is to use "cool" materials that reflect light, such as white paint and light-colored asphalt. It turns out that adding luminescent materials can help even more.

Anna Laura Pisello and colleagues at the University of Perugia are trying to create practical pavements that glow in the dark. They are experimenting with different luminescent substances, and testing how to add them to pavement material to get the best performance and durability. Above are samples of luminescent materials and a paving stone in which they have been embedded.
Anna Laura Pisello and colleagues at the University of Perugia are trying to create practical pavements that glow in the dark. They are experimenting with different luminescent substances, and testing how to add them to pavement material to get the best performance and durability. Above are samples of luminescent materials and a paving stone in which they have been embedded.

At the Lawrence Berkeley Lab, Berdahl and his team experimented with synthetic ruby, a material that is luminescent while in sunlight, to make colored coatings that stayed cool. In an early experiment, they reported that a ruby-pigmented surface stayed cooler in the sun than a similarly colored material without the special pigment.

Pisello's lab went one step further and added several persistently luminescent materials — ones that stored light energy and gave it off slowly — to concrete. Compared with non-luminescent surfaces of the same color, the best of them lowered the surrounding air temperature on sunny days by up to 3.3°C.

"You can make [a surface] as reflective as possible. But can you go beyond that? The idea is that maybe you can go a little bit beyond that using persistent luminescence as another way to transfer energy out … It is interesting," Patrick E. Phelan, a mechanical engineer at Arizona State University who coauthored a paper on the urban heat island effect in the "Annual Review of Environment and Resources," said.

There are 250 known luminescent materials, many of them not yet studied for practical applications. Pisello says there is a potential for glowing paints and pavements that last longer and shine brighter in more colors.

"In the short term, the best and easiest solution is to improve what we already have," she said. That includes tweaking materials so that they give out light longer, more strongly, or in different colors, and making sure they continue to work in real-world environments.

In the longer term, she adds, new classes of engineered materials could work even better. For instance, one could turn to "quantum dots" — tiny semiconducting particles that can be made to glow and that are already used in biological 

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