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MIT conductive concrete consortium cements five-year research agreement with Japanese industry

The MIT EC^3 Hub, an outgrowth of the MIT Concrete Sustainability Hub, will develop multifunctional concrete applications for infrastructure.
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Six people stand behind a long desk with Japanese characters projected behind them. Two men hold a signed agreement.
Caption:
Left to right: Jewan Bae (director, OCR); MIT professors Yang Shao Horn, Admir Masic, and Franz-Josef Ulm; Yoshihiro Aizawa (CEO, Aizawa Concrete); and Seiji Nakemura (Aizawa Concrete)
Credits:
Photo courtesy of Aizawa Concrete.

The MIT Electron-conductive Cement-based Materials Hub (EC^3 Hub), an outgrowth of the MIT Concrete Sustainability Hub (CSHub), has been established by a five-year sponsored research agreement with the Aizawa Concrete Corp. In particular, the EC^3 Hub will investigate the infrastructure applications of multifunctional concrete — concrete having capacities beyond serving as a structural element, such as functioning as a “battery” for renewable energy

Enabled by the MIT Industrial Liaison Program, the newly formed EC^3 Hub represents a large industry-academia collaboration between the MIT CSHub, researchers across MIT, and a Japanese industry consortium led by Aizawa Concrete, a leader in the more sustainable development of concrete structures, which is funding the effort.  

Under this agreement, the EC^3 Hub will focus on two key areas of research: developing self-heating pavement systems and energy storage solutions for sustainable infrastructure systems. “It is an honor for Aizawa Concrete to be associated with the scaling up of this transformational technology from MIT labs to the industrial scale,” says Aizawa Concrete CEO Yoshihiro Aizawa. “This is a project we believe will have a fundamental impact not only on the decarbonization of the industry, but on our societies at large.” 

By running current through carbon black-doped concrete pavements, the EC^3 Hub’s technology could allow cities and municipalities to de-ice road and sidewalk surfaces at scale, improving safety for drivers and pedestrians in icy conditions. The potential for concrete to store energy from renewable sources — a topic widely covered by news outlets — could allow concrete to serve as a “battery” for technologies such as solar, wind, and tidal power generation, which cannot produce a consistent amount of energy (for example, when a cloudy day inhibits a solar panel’s output). Due to the scarcity of the ingredients used in many batteries, such as lithium-ion cells, this technology offers an alternative for renewable energy storage at scale. 

Ice placed on top of a charged conductive cement panel melts due to the higher temperature of the surface.
Carbon black doped concrete pavements can have current run through them to heat their surfaces, allowing for de-icing. If implemented for city roads and sidewalks, this technology could have benefits for pedestrian and vehicular safety.
Photo courtesy of the MIT EC^3 Hub and Aizawa Concrete.

A researcher stands with a microphone in the other hand. In the other hand, he holds a laser thermometer, which is aimed at a self-heating conductive cement surface
Professor Admir Masic, EC^3 Hub’s founding faculty director, demonstrates the self-heating capability of carbon black doped concrete pavements with a laser thermometer, showing the difference between the pavement surface temperature and the ambient temperature.
Photo courtesy of the MIT EC^3 Hub and Aizawa Concrete.

A large fiberglass cylinder containing conductive concrete is resting on top of a table. On top of the cylinder, a converter allows the device to power LED lights. The converter is connected to a multimeter.
A charged carbon-cement supercapacitor powers multiple LED lights and is connected to a multimeter to measure the system’s voltage at 12 volts.
Photo courtesy of the MIT EC^3 Hub and Aizawa Concrete.

Regarding the collaborative research agreement, the EC^3 Hub’s founding faculty director, Professor Admir Masic, notes that “this is the type of investment in our new conductive cement-based materials technology which will propel it from our lab bench onto the infrastructure market.” Masic is also an associate professor in the MIT Department of Civil and Environmental Engineering, as well as a principal investigator within the MIT CSHub, among other appointments.

For the April 11 signing of the agreement, Masic was joined in Fukushima, Japan, by MIT colleagues Franz-Josef Ulm, a professor of Civil and Environmental Engineering and faculty director of the MIT CSHub; Yang Shao-Horn, the JR East Professor of Engineering, professor of mechanical engineering, and professor of materials science and engineering; and Jewan Bae, director of MIT Corporate Relations. Ulm and Masic will co-direct the EC^3 Hub.

The EC^3 Hub envisions a close collaboration between MIT engineers and scientists as well as the Aizawa-led Japanese industry consortium for the development of breakthrough innovations for multifunctional infrastructure systems. In addition to higher-strength materials, these systems may be implemented for a variety of novel functions such as roads capable of charging electric vehicles as they drive along them.

Members of the EC^3 Hub will engage with the active stakeholder community within the MIT CSHub to accelerate the industry’s transition to carbon neutrality. The EC^3 Hub will also open opportunities for the MIT community to engage with the large infrastructure industry sector for decarbonization through innovation. 

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