A concrete material developed at the University of Michigan can heal itself when it cracks. No human intervention is necessary – just water and carbon dioxide.
A handful of drizzly days would be enough to mend a damaged bridge made of the new substance. Self-healing is possible because the material is designed to bend and crack in narrow hairlines rather than break and split in wide gaps, as traditional concrete behaves.
“It’s like if you get a small cut on your hand, your body can heal itself. But if you have a large wound, your body needs help. You might need stitches. We’ve created a material with such tiny crack widths that it takes care of the healing by itself. Even if you overload it, the cracks stay small,” said Victor Li, the E Benjamin Wylie Collegiate Professor of Civil Engineering and a professor of Materials Science and Engineering.
A paper about the material is published online in Cement and Concrete Research. It will be printed in a forthcoming edition of the journal.
In Li’s lab, self-healed specimens recovered most if not all of their original strength after researchers subjected them to a 3 per cent tensile strain. That means they stretched the specimens to 3 per cent beyond their initial size. It’s the equivalent of stretching a 30-metre piece an extra metre – enough strain to severely deform metal or catastrophically fracture traditional concrete.
“We found, to our happy surprise, that when we load it again after it heals, it behaves just like new, with practically the same stiffness and strength,” Li said. “Self-healing of crack damage recovers any stiffness lost when the material was damaged and returns it to its pristine state. The material can be damaged and still remain safe to load.”
The engineers found that cracks must be kept below 150 micrometers, and preferably below 50, for full healing. To accomplish this, Li and his team improved the bendable engineered cement composite, or ECC, they’ve been developing for the past 15 years.
More flexible than traditional concrete, ECC acts more like metal than glass. Traditional concrete is considered a ceramic. Brittle and rigid, it can suffer catastrophic failure when strained in an earthquake or by routine overuse, Li said. But flexible ECC bends without breaking. It is studded with specially-coated reinforcing fibres that hold it together. ECC remains intact and safe to use at tensile strains up to 5 per cent. Traditional concrete fractures and can’t carry a load at .01 per cent tensile strain.
The average crack width in Li’s self-healing concrete is below 60 micrometers. That’s about half the width of a human hair. His recipe ensures that extra dry cement in the concrete exposed on the crack surfaces can react with water and carbon dioxide to heal and form a thin white scar of calcium carbonate. Calcium carbonate is a strong compound found naturally in seashells. In the lab, the material requires between one and five cycles of wetting and drying to heal.
To test the healed concrete, the researchers used resonant frequency measurements to determine the stiffness and strength before and after inducing the cracks. These tests send sound waves through the material to detect changes in its structure.
Today, builders reinforce concrete structures with steel bars to keep cracks as small as possible. But they’re not small enough to heal, so water and deicing salts can penetrate to the steel, causing corrosion that further weakens the structure. Li’s self-healing concrete needs no steel reinforcement to keep crack width tight, so it eliminates corrosion.
The professor says this new substance could make infrastructure safer and more durable. By reversing the typical deterioration process, the concrete could reduce the cost and environmental impacts of making new structures. And repairs would last longer.
“Our hope is that when we rebuild our roads and bridges, we do it right, so that this transportation infrastructure does not have to undergo the expensive repair and rebuilding process again in another five to 10 years,” Li said. “Also, rebuilding with self-healing bendable concrete would allow a more harmonious relationship between the built and natural environments by reducing the energy and carbon footprints of these infrastructures. As civil and environmental engineers, we are stewards of these mega-systems. Advanced materials technology is one means to keep them healthy.”
The University is pursuing patent protection for the intellectual property, and is seeking commercialisation partners to help bring the technology to market.