Mashable spotlights how MIT’s baseball pitching coach is using motion capture technology to help analyze and teach pitching techniques. Using the technology, Coach Todd Carroll can “suggest real-time adjustments as a player is pitching so that just one session using the technology improves their game.”
Washington Post reporter Dalvin Brown spotlights Nextiles, a company spun out of MIT and the NSF that has crafted machine-washable smart fabrics that capture biometric data. “Just imagine all the biochemicals that come out of you and get released into your clothes,” says Prof. Yoel Fink of the future of e-textiles. “Today, all of that stuff gets erased in the washing machine. But at some point, your fabric could learn, listen to subtle changes, and alert you to go to the doctor for a checkup.”
Mashable reporter Jordan Aaron spotlights how MIT researchers have developed insect-sized drones that can flap their wings over 500 times per second, allowing them to withstand collisions. The drones are “powered by a small actuator, which gives them the ability to flap so fast.”
Prof. Kevin Chen speaks with NPR about his work developing a new microdrone inspired by how an insect flaps its wings. “Because our soft power robot is very robust, of course, we can do interesting maneuvers, such as doing a somersault, we can survive collisions, et cetera,” he explains.
Speaking with WHDH, Prof. Kevin Cheng explains how he was inspired by the agility of insects to create tiny new drones that are acrobatic and resilient. “Think about a scenario, for example, a building collapse with people trapped inside, and what we’re thinking of is sending a swarm of drones into this collapsed building to search for survivors,” says Chen. “That’s something very difficult for traditional drones.”
Writing for Boston.com, Mark Gartsbeyn highlights how MIT researchers have “developed tiny drones that can fly, dodge, and weave like actual insects.”
MIT researchers have developed tiny, agile drones with insect-like wings, reports John Biggs for Gizmodo. “The goal is to use these tiny, soft drones to explore close spaces where rigid drones will break on contact with hard surfaces,” writes Biggs.
TechCrunch reporter Brian Heater spotlights how MIT researchers have designed insect-sized drones that can withstand collisions. Heater notes that potential applications for the new drones include everything from “simple inspections currently being handled by larger models to pollination and search and rescue.”
MIT researchers have developed a new atomic clock that can keep time more precisely thanks to the use of entangled atoms, reports Leila Stein for Popular Mechanics. “If all atomic clocks worked the way this one does then their timing, over the entire age of the universe, would be less than 100 milliseconds off,” Stein writes.
Writing for Popular Mechanics, Leila Stein highlights how MIT researchers have created a perfect fluid and captured its sound. “To record the sound, the team of physicists sent a glissando of sound waves through a controlled gas of elementary particles called fermions,” Stein writes.
Prof. Martin Zwierlein speaks with Edgar Herwick III of GBH Radio about his work capturing the sound of a “perfect” fluid. "It was a beautiful sound," says Zwierlein. "It was a quantum sound. In a way it was the most long-lasting sound that you can imagine given the laws of quantum mechanics.”
Prof. James Fujimoto and research affiliate Eric Swanson have been named recipients of the Sanford and Sue Greenberg Prize to End Blindness, reports Sandrine Ceurstemont for National Geographic. “The winners were chosen based on the strength of their contributions to eliminate blindness, the ambitious aim set out by the prize organizers in 2012,” Ceurstemont explains.
New Scientist reporter Abigail Beall spotlights how MIT researchers have listened to sound waves traveling through a "perfect" fluid, which could shed light on the resonant frequencies within a neutron star. “The quality of the resonances tells me about the fluid’s viscosity, or sound diffusivity,” says Prof. Martin Zwierlein. “If a fluid has low viscosity, it can build up a very strong sound wave and be very loud, if hit at just the right frequency. If it’s a very viscous fluid, then it doesn’t have any good resonances.”
Scientific American reporter Daniel Garisto spotlights how a team of MIT researchers has uncovered hints of anomalous activity in heavy isotopes. “We’re not claiming to have discovered anything like a new particle,” says Prof. Vladan Vuletić. “Most likely, we are measuring new nuclear physics, but there is the possibility of something else going on.”
TechCrunch reporter Taylor Hatmaker writes that MIT researchers will led a new NSF-funded research institute focused on AI and physics.