MIT researchers have improved a new type of “concrete battery” by tenfold, paving the way for its use in turning buildings, bridges and sidewalks into giant energy stores capable of powering entire cities.

The material is called electron-conducting carbon concrete — or ec³ — and is made by combining cement, water, a common liquid electrolyte and an extremely fine carbon powder called nanoscale carbon black. When mixed together, the ingredients create a dense, conductive network capable of carrying an electrical charge. Once set into concrete, the material and anything built from it (whether they’re buildings and bridges or pavements) is able to store and release energy as needed.

It’s a concept known as supercapacitive energy storage, and researchers hope it can offer a viable solution to one of renewable energy’s biggest challenges: namely, how to store power locally when the sun isn’t shining or the wind isn’t blowing.

In a new study in the journal Proceedings of the National Academy of Sciences (PNAS), researchers said they achieved a tenfold increase in the energy storage capacity of ec³ since 2023. Fivecubic meters (176.5 cubic feet) of the material can now store more than 10 kilowatt-hours of electricity — roughly enough to power a typical household for a day.

Just two years ago, achieving that level of storage would have required nine times the volume, the team said. “With these higher energy densities and demonstrated value across a broader application space, we now have a powerful and flexible tool that can help us address a wide range of persistent energy challenges,” lead author of the study Damian Stefaniuk, research scientist at MIT, said in a statement.

“One of our biggest motivations was to help enable the renewable energy transition. Solar power, for example, has come a long way in terms of efficiency. However, it can only generate power when there’s enough sunlight. So, the question becomes: How do you meet your energy needs at night, or on cloudy days?”

While ec³ doesn’t match the energy density of traditional battery technologies like lithium-ion (which pack hundreds of times more energy into the same weight or volume), the fact that it can be cast directly into building components and may last as long as the structure itself, without relying on scarce or toxic materials, makes it especially attractive to scientists.