MIT.nano

Prof. Jesús del Alamo speaks with Ann Fisher of WOSU’s All Sides with Ann Fisher about the importance of supporting domestic chip manufacturing in the U.S., and the need to help encourage students to pursue careers in the semiconductor industry. “Universities and colleges train over 50% of the semiconductor workforce,” says del Alamo, “and so investing in education, investing in the infrastructure, both human but also physical infrastructure that supports education and research, is really critical in the long run.” 

MIT researchers have created a thin, lightweight and flexible loudspeaker that is as thin as a few sheets of paper and can stick to most surfaces while producing high quality sound, reports Kendra Redmond for Science News Explores. “Because the design is so flexible and durable, companies could potentially integrate speakers into T-shirts or other personal items,” writes Redmond. “Or users could make their own.”

Ross Trethewey, co-host of This Old House, visits Prof. Vladimir Bulović, director of MIT.nano, to learn more about the future of solar technology, including an electricity-generating film that can be applied to windows and other materials. “Dramatic advancements are on the horizon,” says Bulović. “We can make solar cells that don’t weigh very much at all so deployment of them on top of your roof could be as simple as unrolling a carpet and stapling it to the roof with a plug. Maybe your windows will be turned into solar cells.” 

MIT researchers have developed a flexible and paper-thin speaker that can turn any surface into an audio source, reports New Scientist. “The lightweight loudspeaker uses only a fraction of the energy of a regular speaker and can generate sound regardless of the surface it is attached to,” writes New Scientist.

A time capsule buried in 1957 by former MIT President James R. Killian and Prof. Harold Edgerton will be unveiled in 2957 a full millennium after its burial, writes Michele Debczak for Salon.

MIT researchers have developed a new ultrathin material that can turn any rigid surface into a speaker, reports Haje Jan Kamps for TechCrunch. “The loudspeaker could be used in active noise cancellation, for example — combine the speaker tech with some electronics and microphones, and it could cancel out sound,” writes Kamps. “The inventors also envision immersive sound experiences, and other low-energy use cases such as smart devices, etc.”

Daily Beast reporter Tony Ho Tran writes that MIT researchers have created a new loudspeaker that is as thin as paper and produces high-quality sound. The paper-thin device “weighs roughly the same as a dime, and can be used to cover surfaces like walls and ceilings,” writes Tran. “The loudspeaker also uses a fraction of the energy a typical speaker requires, while producing comparable sound quality.”

MIT researchers have developed an ultrathin speaker that can be applied to surfaces like wallpaper, reports Andrew Liszewski for Gizmodo. “The applications for the thin-film speaker material are endless,” writes Liszewski. “In addition to being applied to interiors like office walls or even the inside of an airplane to cancel out unwanted noises, an entire car could be wrapped in a speaker, making it easier to alert pedestrians that an otherwise silent electric vehicle was approaching.”

The MIT AI Hardware Program seeks to bring together researchers from academia and industry to “examine each step of designing and manufacturing the hardware behind AI-powered technologies,” reports Emily Bamforth for EdScoop. “This program is about accelerating the development of new hardware to implement AI algorithms so we can do justice to the capabilities that computer scientists are developing,” explains Prof. Jesús del Alamo.

The MIT AI Hardware Program is aimed at bringing together academia and industry to develop energy-optimized machine-learning and quantum-computing systems, reports Katyanna Quach for The Register. “As progress in algorithms and data sets continues at a brisk pace, hardware must keep up or the promise of AI will not be realized,” explains Professor Jesús del Alamo. “That is why it is critically important that research takes place on AI hardware."

U.S. Secretary of Commerce Gina Raimondo visited MIT.nano this week, where she emphasized the importance of investing in semiconductor research and manufacturing, and noted that MIT is the “gold standard” for collaboration between academia and industry, reports Jake Freudberg for GBH News. “Ultimately, what we need is the great ideas and research that are beginning in universities to be turned into products made at scale in America,” said Raimondo.

WCBV reporter Sharman Sacchetti spotlights U.S. Commerce Secretary Gina Raimondo’s visit to MIT.nano. “Investing in chip manufacturing and supply chain domestically will allow us to make more goods in America, which will bring down inflation,” said Raimondo of the importance of boosting domestic manufacturing of semiconductors.

Prof. Jesús del Alamo speaks with Bloomberg Radio’s Janet Wu about a new report by MIT researchers that explores how the U.S. can regain leadership in semiconductor manufacturing and production. “Leadership in microelectronics is really critical for economic progress and also security concerns,” says del Alamo.

A new white paper by MIT researchers underscores the importance of regaining the U.S.’s innovation leadership in the area of semiconductor manufacturing and calls for increased investment at the research level to help advance this field, reports Stephen Shankland for CNET. "The hollowing out of semiconductor manufacturing in the US is compromising our ability to innovate in this space and puts at risk our command of the next technological revolution,” write the report’s authors. “To ensure long-term leadership, leading-edge semiconductor manufacturing in the US must be prioritized and universities activities have to get closer to it."

MIT researchers have developed a new technique for producing low-voltage, power-dense actuators that can propel flying microrobots, reports Danica D'Souza for Mashable. “The new technique lets them make soft actuators that can carry 80 percent more payload,” D’Souza reports.