New insights about a tiny snail that lives on the ocean floor could help scientists design better armor for soldiers and vehicles, according to MIT researchers.
A team of materials scientists, led by MIT Associate Professor Christine Ortiz, report that the shell of the so-called "scaly-foot" snail is unlike any other naturally occurring or manmade armor. The study suggests that its unique three-layer structure dissipates energy that would cause weaker shells to fracture.
Copying various aspects of the structure could help scientists design better armor for military use, says Ortiz, who is a member of MIT's Institute for Soldier Nanotechnologies. The new study was partly funded by the Army and the Department of Defense and will appear in the Proceedings of the National Academy of Sciences the week of Jan. 18.
Ortiz' attention was drawn to this interesting gastropod in 2003, when its discovery was first reported. The snail lives in a relatively harsh environment on the floor of the Indian Ocean, near hydrothermal vents that spew hot water. Therefore it is exposed to fluctuations in temperature as well as high acidity, and also faces attack from predators such as crabs and other snail species.
When a crab attacks a snail, it grasps the snail's shell with its claws and squeezes it until it breaks—for days if necessary. The claws generate mechanical energy that eventually fractures the shell, unless it is strong enough to resist.
In the new paper, Ortiz and her colleagues, including MIT Dean of Engineering Subra Suresh, report that the shell of the hot vent gasotropod has several features that help dissipate mechanical energy from a potential penetrating predatory attack. Of particular importance is its tri-layered shell structure, which consists of an outer layer embedded with iron sulfide granules, a thick organic middle layer, and a calcified inner layer.
Most other snail shells have a calcified layer with a thin organic coating on the outside. In the scaly foot gastropod, simulations suggest that the relatively thick organic middle layer can absorb much energy during a penetrating attack. It may also help to dissipate heat and thermal fluctuations exhibited near hydrothermal vents.
How they did it: Ortiz and her colleagues measured the mechanical properties of the snail shell using a machine called an indenter, which has a diamond tip. By measuring the force applied to the shell, and the shell's resulting displacement, they can calculate its mechanical properties.
Next steps: Ortiz is looking at host of natural exoskeletons in order to extract protective design principles, including chitons, urchins, beetles, and armored fish.
Citation: "Protection mechanisms of the iron-plated armor of a deep-sea hydrothermal vent gastropod," Haimin Yao et al. Proceedings of the National Academy of Sciences, week of Jan. 18, 2010.
Funding: National Science Foundation, Singapore-MIT Alliance, U.S. Army through the MIT Institute for Soldier Nanotechnologies, Raytheon, and the National Security Science and Engineering Faculty Fellowship Program.
