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Science

Tough-as-nails ceramic inspired by mother-of-pearl

By Ben Coxworth
March 25, 2014
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The synthetic mother-of-pearl ceramic (left) and its natural counterpart
The synthetic mother-of-pearl ceramic (left) and its natural counterpart
A crack goes right through a piece of regular ceramic (left), but is stopped in the nacre-like material

Although you may know it simply as the shiny iridescent stuff on the inside of mollusk shells, mother-of-pearl (or nacre) is a remarkable material. It allows those shells, which otherwise consist almost entirely of brittle calcium carbonate, to stand up to the abuses of life in the sea. Now, a team led by the Laboratoire de Synthèse et Fonctionnalisation des Céramiques (CNRS) in Paris, has copied the structure of nacre to create a ceramic material that's almost 10 times stronger than conventional ceramics.

Natural nacre consists of layers of microscopic tablet-like blocks, that have wavy edges not unlike jig-saw puzzle pieces. This means that when the material is subjected to mechanical stress, any cracks that start to form in the boundary lines between the tablets have to follow a very circuitous route. As a result, all but the largest cracks simply just peter out.

Scientists at Montreal's McGill University recently created super-strong glass, by etching nacre boundary line-like cracks in glass microscope slides. The CNRS team, however, took a different approach with the ceramic.

They started with a ceramic powder, made up of microscopic alumina platelets. That powder was suspended in water, and the resulting solution was then frozen. The ice crystallization process caused the platelets to self-assemble into stacks, the boundaries between which were similar to the wavy boundaries between nacre tablets. A high-temperature process was then used to increase the density of the material, thus removing the water.

In lab tests of the resulting ceramic, it was found that cracks had great difficulty spreading through it – as is the case with real nacre.

Additionally, the scientists state that the process should work with any type of ceramic powder (not just alumina), and it should be easy to scale up to industrial production levels. Besides simply making existing types of ceramic items stronger, the technology could also allow them to stay at the same strength, but be made much smaller.

A paper on the research was recently published in the journal Nature Materials.

Source: CNRS

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ScienceBiomimicryCeramicsCNRS
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Ben Coxworth
Based out of Edmonton, Canada, Ben Coxworth has been writing for New Atlas since 2009 and is presently Managing Editor for North America. An experienced freelance writer, he previously obtained an English BA from the University of Saskatchewan, then spent over 20 years working in various markets as a television reporter, producer and news videographer. Ben is particularly interested in scientific innovation, human-powered transportation, and the marine environment.
6 comments
Julius Siador
Now, a thinner ceramic engine would be possible to significantly lower the manufacturing cost.
Mel Tisdale
If this process can be adapted for use in 3D printing, then we can forget anything in the way of meaningful gun legislation. While we are in the forgetting business, until the invention of a ceramics detector, if such a thing is possible, we can probably forget any hope of stopping terrorists armed with handguns from boarding airliners, with all that that implies.
HighPockets
Note nature's nacre is neater.
Bruce H. Anderson
Ceramics are kind of brittle, and it would be interesting to see a mechanical properties comparison of the resulting nacre-like material to other materials like polymers or metals.
VirtualGathis
@Mel Tisdale - Unless we make the backscatter machines mandatory. Talk about the ultimate violation of the expectation of privacy though.
Gary Richardson
Maybe this will lead to more durable artificial joint replacements.
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