快猫短视频

Mystery mechanism heals high-tech composite

A new material that fixes its own cracks could make bridges and planes safer, but scientists don't quite understand how it works
The composite material with a magnified detail (inset), showing the microcapsules of liquid adhesive
The composite material with a magnified detail (inset), showing the microcapsules of liquid adhesive
(Image: Mary Caruso)

Self-healing composite materials that can fix small cracks in the structures of planes, bridges, and wind turbines could become more cost-effective thanks to a new bonding mechanism discovered by researchers in the US.

Engineers have high hopes for composite materials that can repair small cracks in their structure. 鈥淲hen you have any damage induced by fatigue, there鈥檚 usually nothing you can do except wait for catastrophic failure,鈥 says , who led the research at the University of Illinois at Urbana-Champaign, Urbana, US.

Self-healing composites should change that. These materials contain capsules of a liquid adhesive which leaks out and repairs tiny cracks when they appear. (Watch a video showing . Animation by the Beckman Institute Imaging Technology Group)

However, the adhesives usually require some kind of post-processing to make them set, such as curing with UV light or heating to high temperatures. What engineers would prefer, though, is a material that healed itself without any extra intervention.

Rare catalyst

In 2001, Moore鈥檚 group developed just such a material that relied on the mixing of two different chemicals that set like a two-part epoxy.

The material contains two types of capsule: one containing a ring hydrocarbon called dicyclopentadiene and the other containing a ruthenium solvent that acts as a catalyst, causing the rings to break open and polymerise. Any crack causes the chemicals to mix and set, bonding the crack faces together.

But ruthenium is rare. 鈥淎n Airbus fuselage has 60,000 pounds of composites in it. If you used the catalyst approach, a significant fraction of the world supply of ruthenium would be flying around in one plane,鈥 Moore told 快猫短视频.

That makes it impractical for most applications, so his team set to work looking for an alternative.

Seeking to improve the approach, the group changed to a nickel-based catalyst, but had to change the solvent as well. The first step was to gauge the new solvent in the absence of a catalyst.

Serendipitous solvent

To their surprise, it worked almost as well. Moore says the solvent was probably dissolving the composite material, allowing it to mix and bond again, although he concedes the exact mechanism remains a mystery.

The group then tested another solvent, using a chemical called chlorobenzene. After fracture and self-healing, the composites containing chlorobenzene recovered up to 100% of their original strength 鈥 as good as new.

And, although toxic, chlorobenzene is a hundred times cheaper than ruthenium and is much more easily available.

鈥淚t鈥檚 a very interesting way forward,鈥 says Ian Bond, a self-healing materials researcher at the University of Bristol. 鈥淚t really improves on the catalyst method.鈥

However, Bond warns that the toxicity of chlorobenzene is likely to make the idea less industrially attractive. Moore鈥檚 team, meanwhile, is testing a number of less toxic, more biodegradable solvents to do the same job.

Journal reference: