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Scientific American reporter Riis Williams explores how MIT researchers created “smart gloves” that have tactile sensors woven into the fabric to help teach piano and make other hands-on activities easier. “Hand-based movements like piano playing are normally really subjective and difficult to record and transfer,” explains graduate student Yiyue Luo. “But with these gloves we are actually able to track one person’s touch experience and share it with another person to improve their tactile learning process.”

A more than $40 million investment to add advanced nano-fabrication equipment and capabilities to MIT.nano will significantly expand the center’s nanofabrication capabilities, reports Jon Chesto for The Boston Globe. The new equipment, which will also be available to scientists outside MIT, will allow “startups and students access to wafer-making equipment used by larger companies. These tools will allow its researchers to make prototypes of an array of microelectronic devices.”

Nature reporter Neil Savage speaks with former members of Prof. Moungi Bawendi’s research group about their work with Bawendi on synthesizing quantum dots. Manoj Nirmal PhD '96 recalls how, “what I was really intrigued and fascinated by was, it was very different than anything else that was happening in the [chemistry] department.” Christopher Murray PhD '95 rejoiced in the Nobel Prize announcement, saying, “It’s extremely exciting to see that what [Moungi] built is recognized as part of the Nobel prize.”

Prof. Moungi Bawendi, recipient of the 2023 Nobel Prize in Chemistry, speaks with CBC Quirks & Quacks host Bob McDonald about his work in quantum dots and nanotechnology. “I really want to stress that the beginning of this field, we were interested in this because it was a brand new material, it was a size region that no one had investigated before,” says Bawendi. “This was before people talked about nanoscience and nanotechnology, we were just very curious how the properties evolved from the molecular properties… to the bulk properties.”

Prof. Moungi Bawendi shares his thoughts at an MIT press conference after being named a recipient of the 2023 Nobel Prize in Chemistry, reports the AFP. “None of us who started this field could have predicted 30 years later, it would be where we are today,” says Bawendi. “And you know it’s just amazing to me. If you have really great people working on a brand new field with brand new materials, innovation comes out in directions that you can’t predict.”

Prof. Moungi Bawendi has been named a recipient of the 2023 Nobel Prize in Chemistry for his work and contributions to the field of quantum dots and nanotechnology, reports Brianna Abbott for The Wall Street Journal. “To understand the physics, which was the motivation, we had to create the material,” says Bawendi. “I would never have thought that you could make them at such a large scale and that they would actually make a difference in the consumer area.”

Prof. Moungi Bawendi, one of the winners of the 2023 Nobel Prize in Chemistry, speaks with Lisa Mullins of WBUR’s All Things Considered. “It's a lot of hard work, a lot of perseverance, and sometimes, you know, you'll work for a few years without seeing any results at all. And then the results come maybe just in a few weeks, and suddenly it happens,” says Bawendi of his advice to students on dealing with progress and failures in their research. “Believing in the end point and just, you know, when things don't work, learning how to solve problems and go maybe a little slightly different direction."

Prof. Mougni Bawendi is one of three scientists who has been awarded the 2023 Nobel Prize in Chemistry for his work with quantum dots, reports Sam Turken for GBH. “Bawendi said that when he first started working with quantum dots, he wasn’t thinking of the potential uses for them,” writes Turken. “He merely wanted to study them, but in order to do that, he had to create dots that were of high quality. Once he did that, their benefits became more clear.”

Boston Globe reporter Aaron Pressman and John R. Ellement spotlight Prof. Moungi Bawendi, one of the winners of the 2023 Nobel Prize in Chemistry, for his work in the discovery and synthesis of quantum dots, “tiny particles used in an array of technologies.” Bawendi noted that he was “deeply honored and surprised and shocked” to receive a Nobel Prize. He added that MIT is, “just a different place in the world. And I’m so grateful that MIT supported me through my career all these years.”

Popular Science reporter Andrew Paul writes that MIT engineers have developed a new chip for smart phones that blocks unwanted signals, which could “greatly reduce production costs, make devices smaller and more efficient, and potentially even improve battery life.” Graduate student Soroush Araei explains that “our research can make your devices work better with fewer dropped calls or poor connections caused by interference from other devices.”

MIT researchers have developed a new hardware that offers faster computation for artificial intelligence with less energy, reports Kyle Wiggers for TechCrunch. “The researchers’ processor uses ‘protonic programmable resistors’ arranged in an array to ‘learn’ skills” explains Wiggers.

Postdoctoral researcher Murat Onen  and his colleagues have created “a nanoscale resistor that transmits protons from one terminal to another,” reports Alex Wilkins for New Scientist. “The resistor uses powerful electric fields to transport protons at very high speeds without damaging or breaking the resistor itself, a problem previous solid-state proton resistors had suffered from,” explains Wilkins.

Prof. Jesús del Alamo speaks with Ira Flatow of NPR’s Science Friday about the importance of the CHIPS Act and the pressing need to invest in semiconductor manufacturing in the U.S. “There is a deep connection between leading-edge manufacturing and innovation,” says del Alamo. “Whoever gets the most advanced technology first in the marketplace is going to rip off the greatest profits, and as a result is going to be able to invest into innovation at a greater level and therefore be able to move faster than their competitors.”

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.” 

Researchers at MIT have developed a wood-like plant material which could eventually serve as a viable wood substitute in various construction projects, reports Tim Newcomb for Popular Mechanics. Researchers adjust “chemicals in the growth process to precisely control the physical and mechanical properties, such as stiffness and density,” explains Newcomb.