A Well a little chaotic, as it happens. When the researchers tested the strength of each network, the Bouligand type IV structure absorbed 20 times more energy than the type I. “This type of microstructure ensures that this type of composite is very strong,” explains Qiming Wang, engineer from the University of Southern California. , co-author on a new paper describe the results in the journal Advanced materials. “When you have a crack, that crack propagates through the torsion pattern to dissipate the energy inside the material.” In fact, the material absorbs more energy than natural mother-of-pearl (mother-of-pearl), which gives some shells their strength, and also beats existing man-made materials, say Wang and his colleagues.
Just as the mantis shrimp hammer absorbs the energy of its punches without slamming, so do materials developed with this new method. For potential uses, Wang says to think of body armor, which must dissipate energy from a bullet. Calcium carbonate is also quite light, so scientists might also be able to grow stronger panels for airplanes, or even skins for the robots, Wang said.
“This is, for me, a way of doing manufacturing in the future, and I’m not the only one saying it,” said Pablo Zavattieri, civil engineer at Purdue University, who was not involved. in this research. In traditional manufacturing, faults can creep in. Nature, on the other hand, has over millions of years developed the wonderful Bouligand structure in the mantis shrimp hammer, and it’s a pattern that can be replicated with a simple trellis and bacteria bath. “Nature is, in this way, impeccable,” says Zavattieri. “Nature is a 3D printer.”
Another thing that makes this bacterial material special is its ability to regenerate itself. Like, what if instead of building roads, we grown up their? “If we have damage, we just have to put bacteria in and that can repel them,” says Wang. “These structures are very strong, very strong and can potentially repair themselves.”
The researchers aren’t there yet – they got the bacteria to grow minerals under controlled laboratory conditions, and even then it was only small amounts. Scaling up road construction would entail additional engineering challenges; for example, getting the right ratio of scaffolding to hardening material. But Zavattieri is already working on 3D printing concrete. “I don’t think it’s super crazy,” he says. “We can totally ask the robots to print the classic scaffolding, leave the bacteria there, and then let them grow the material for 10 days.”
So maybe one day the shameless mantis shrimp bashing could help mend America’s Broken Infrastructure, instead of just breaking your thumbs.
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