MIT researchers have developed a new water-based material that could be used to make artificial skin, long-lasting contact lenses and drug-delivering bandages, writes Jamie Ducharme for Boston Magazine. “It’s interesting to imagine a world where your medicine cabinet is stocked with hydrogel-elastomer hybrids instead of contact lenses and Band-Aids,” writes Ducharme.
Umair Irfan of ClimateWire writes that a new paper by Prof. Jessika Trancik finds that renewable energy storage can be a good investment, and provides insight on which storage technologies are the most economically feasible. “One of the major technology challenges of scaling up renewables is developing economically feasible energy storage," says Jessika Trancik.
In this video, BBC World News reporter Adam Shaw learns about the stretchy, water-based hydrogel MIT researchers developed that could be used as a smart bandage to sense temperatures and deliver medication. “This is a new way to think about this interface between the human body and electronic devices,” explains Prof. Xuanhe Zhao.
Boston.com reporter Sanjay Salomon writes about how “Duckietown,” a model city developed by MIT researchers, could help make self-driving cars a reality. “We realized if you scale down autonomous driving to something very small there’s lots of research to do on a smaller scale with none of the logistical challenges of real autonomous vehicle research,” explains postdoc Liam Paull.
MIT researchers have developed a device that enables solar cells to convert the sun’s heat into usable energy, reports Mary Beth Griggs for Popular Science. Griggs explains that “this new method could double the amount of power produced by a given area of solar panels.”
In a video for The New York Times, James Gorman highlights how researchers from MIT and Harvard have developed a robot that can perch on a variety of surfaces. Gorman explains that “perching is the next frontier for tiny flying machines because robots, like birds, bats and insects, can keep going longer if they conserve energy by resting.”
BBC News reporter Nathan Tauger writes that researchers from MIT and other institutions have created a miniature robot that can perch like an insect. MIT graduate student Moritz Graule explains that perching solves the problem posed by the fact that “hovering microrobots run out of energy really quickly."
MIT researchers have developed a tiny robot that can perch like an insect, writes G. Clay Whittaker for Popular Science. “It's a widely applicable breakthrough that will, for instance, keep future robots perched while they wait for instructions,” Clay explains.
Popular Science reporter Christine Jun writes that the MIT team has unveiled the pod they developed to compete in the SpaceX Hyperloop competition. Jun explains that the MIT team’s pod is “8 feet long, weighs 500 pounds, and is expected to reach speeds up to 230 miles per hour with an acceleration of 2.4 Gs.”
Writing for Scientific American, Larry Greenemeier explores the pod the MIT Hyperloop team developed to compete in the upcoming SpaceX Hyperloop competition. “One of the most interesting parts of the Hyperloop is the attempt to go significantly faster than any other type of land travel,” says MIT team member and graduate student Greg Monahan.
In this video, Dave Lee reports for the BBC News from the MIT Hyperloop team’s unveiling event, during which the team revealed the prototype pod they designed for the SpaceX Hyperloop competition. Lee explains that the MIT team developed a “droplet-shaped pod [that] uses magnets to lift itself off the aluminum track, reducing friction.”
Bloomberg West broadcasts live from the MIT campus in a special segment highlighting cutting-edge research underway across campus and MIT’s role in driving innovation. “In general, technology can help people,” says Prof. John Leonard. “That’s one of the things I believe as an MIT professor is that technology can make the world a better place.”
PBS NewsHour correspondent Miles O’Brien visits MIT to see the Hyperloop team in action as they work on building a prototype pod that would travel on a high-speed transportation system. O’Brien explains that the MIT team is “testing arrays of common magnets that would levitate the pod over an aluminum track.”
Boston Globe reporter Steve Annear speaks with Prof. Amos Winter about this year’s 2.007 robot competition, during which student-built robots will compete on an American Revolution-themed course. “I think this is one of the most real-life engineering experiences the students can get,” says Winter.
In this video, Bloomberg News reporter Sam Grobart examines the new hydrogel developed by MIT researchers that can bend and twist without breaking, and could be used to deliver medicines and monitor our health. Grobart explains that the hydrogel “could be a building block of the medicine of the future.”