URI research on self-healing concrete yields cost-effective system to extend life of structures

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KINGSTON, R.I. – May 25, 2010 – Efforts to extend the life of structures and reduce repair costs have led engineers to develop “smart materials” that have self-healing properties, but many of these new materials are difficult to commercialize. A new self-healing concrete developed and tested by a graduate student at the University of Rhode Island, however, may prove to be cost-effective.

Michelle Pelletier, a URI master’s degree candidate, embedded a microencapsulated sodium silicate healing agent directly into a concrete matrix. When tiny stress cracks begin to form in the concrete, the capsules rupture and release the healing agent into the adjacent areas.

The sodium silicate reacts with the calcium hydroxide naturally present in the concrete to form a calcium-silica-hydrate product to heal the cracks and block the pores in the concrete. The chemical reaction creates a gel-like material that hardens in about one week.

“Smart materials usually have an environmental trigger that causes the healing to occur,” explained Pelletier, who is collaborating on the project with URI Chemical Engineering Professor Arijit Bose. “What’s special about our material is that it can have a localized and targeted release of the healing agent only in the areas that really need it.”

In tests comparing a standard concrete mix to concrete containing two percent sodium silicate healing agent, Pelletier’s healing mix recovered 26 percent of its original strength (after being stressed to near breaking) versus just 10 percent recovery by the standard mix. The URI student said that an increase in the quantity of healing agent would likely further improve the recovered strength of the concrete.

“Self-healing concrete is a big research field right now,” she said. “But many of the approaches being taken by other researchers have not ended up being economically feasible for commercial production.”

Pelletier noted that some researchers have laced the concrete with bacteria spores that secrete calcium carbonate to fill the cracks and pores, while others embedded glass capillaries with a healing agent, but the process of filling the capillaries with the agent is long and tedious.

Next up for Pelletier is a study to see if her sodium silicate healing agent could also act as a corrosion inhibitor.

“Building concrete is routinely fixed with steel reinforcement bars to compensate for low tensile strength, but they are extremely susceptible to corrosion,” Pelletier said. “We are exploring if the release of the agent will result in corrosion inhibition by two mechanisms. First, the reduced water transport due to the filled pores and reduced interconnectivity within the matrix may result in less moisture reaching the metal and ultimately less corrosion. Also, silicates can deposit on the surface to form a protective film which may also help with reducing the corrosion rate of the steel rebars.”

One additional advantage to the use of self-healing concrete is that it could reduce the significant CO2 emissions that result from concrete production. Because the production of concrete is very energy intensive – when mining, transportation and concrete plants are considered – the industry is responsible for about 10 percent of all CO2 emissions in the United States.

“If self-healing concrete can lengthen the life of the concrete and reduce maintenance and repairs, it will ultimately reduce the production of excess amounts of concrete and result in a decrease in CO2 emissions,” she said.

Pictured above

Michelle Pelletier

URI Department of Communications & Marketing photo by Michael Salerno Photography.