MIT researchers have found that mechanical training could be used to produce synthetic hydrogels that perform more like human muscles, reports Sam Spiller for Popular Mechanics. “Stretched and treated to a mechanical workout in a water bath, the [hydrogels] became unyielding and resistant to molecular ruptures,” writes Spiller. “They were able to stay structurally sound despite continuous repetitive movements.”
Kate Baggaley of NBC News highlights a team of MIT researchers who have developed a computer model to explain how albatrosses fly so efficiently. “Unlike other birds that flap their wings frequently, the albatross rides the wind,” which researchers are hoping to duplicate as they attempt to create drones that fly by harnessing power from the wind and sun, she explains.
Ben Guarino of The Washington Post revisits research by Profs. Annette Hosoi and Amos Winter examining how razor claims burrow through sand. Hosoi and Winter developed a device that “mimics the razor clam's digging ability, allowing an object to secure itself to the sea floor,” and could be used to anchor underwater autonomous vehicles or deposit undersea cables.
CBC reporter Nora Young explores how MIT researchers have developed a new material, inspired by beaver fur, that could help keep surfers warm. “In sports technology there's a great need for textiles that have great insulating properties in water, but still let you stay agile and nimble,” explains graduate student Alice Nasto.
Graduate student Alice Nasto speaks with Cynthia Graber of Scientific American about her research designing a material inspired by the fur that keeps beavers and sea otters warm. Nasto explains that the fur "evolved to trap air, and this air provides a layer of insulation for them in water.”
Researchers from MIT and Harvard have identified the optical features within a limpet’s shell that allow the mollusk to display blue stripes, reports Nidhi Subbaraman for BetaBoston. The findings could inspire developments in augmented reality screens.
“A team from MIT and Duke created flexible polymers that can change color and texture in response to a controlled voltage, essentially allowing them to camouflage an object with the flip of a switch,” reports Jim Festante for Slate. This mimics the ability of cephalopods in nature to rapidly change color.
Professor Xuanhe Zhao has developed a material that mimics the ability of cephalopods such as cuttlefish, squids, and octopuses, to rapidly change color, reports Rachel Feltman for The Washington Post. "It's a fantastic quality, and one unprecedented in human engineering," says Zhao.