In nature, the rafts allow fire ants to survive epic rainstorms in their native Brazil. In the lab, they could help inspire designs for small, swarming robots that might someday be used to explore inaccessible areas or even clean up oil spills.
“The ant raft, up to this point, has been little more than just categorized and documented,” said mechanical engineer Nathan Mlot of the Georgia Institute of Technology, lead author of a paper in the April 25 Proceedings of the National Academy of Sciences. “We were coming at it from an engineering perspective.”
Even though ants’ exoskeletons naturally repel water, a lone ant dropped in a bucket will flounder. But whole colonies of fire ants can float downstream for weeks at a time when flushed from their underground nests. Mlot and his graduate advisor, David Hu, wondered what held the dense mass afloat — and whether it could be harnessed for other applications.
“How are the ants actually linking in the raft?” Mlot said. “We could speculate all we wanted, but the only way to know for sure was to get visual data.”
Mlot’s team collected thousands of fire ants (Solenopsis invicta) by roadsides in Atlanta, where the stinging pests are an invasive species. They immediately noticed that clumps of ants take on the consistency of soft playdough. Ant masses flow like honey or ketchup, and can be described using equations usually found in fluid dynamics.
“You could pick up a cluster of these ants and mold it in your hand. You could form it into a ball and toss it up in the air, and all the ants would stay together in one ball,” Mlot said. “They’re almost like a material.”
To set up a reproducible experiment, the team molded ants into balls by swirling them in a beaker. The ants’ natural tendency to stick together made them clump into near-perfect spheres.
Then the researchers placed balls of 500 to 8,000 ants into a water-filled filled container. Th ant sphere almost immediately relaxed into a flat, pancake-shaped raft, with ants on bottom forming a stable layer for the rest of the colony to rest on.
Surprisingly, the whole swarming mass remained delicately balanced atop the water’s surface. When the researchers tried to submerge the raft, water underneath deformed like a stretchy fabric, conforming to the raft’s underside contours.(wired.com)