Prof. Pablo Jarillo-Herrero speaks with Gizmodo reporter Ryan Mandelbaum about his work showing that when twisted to the right angle, graphene can serve as an insulator or semiconductor. “This sort of field of ‘twistronics’ is something with great potential in terms of scientific discovery and intellectual interest,” Jarillo-Herrero explains.
Reporting for Scientific American’s “60-Second Science” podcast, Christopher Intagliata explores how MIT developed a device, called a rectenna, that can capture energy from Wi-Fi signals and convert them into electricity. The scientists “envision a smart city where buildings, bridges and highways are studded with tiny sensors to monitor their structural health, each sensor with its own rectenna,” Intagliata explains.
Scientific American reporter Jeff Hecht writes that MIT researchers developed a new flexible material that can harvest energy from wireless signals. “The future of electronics is bringing intelligence to every single object from our clothes to our desks and to our infrastructure,” explains Prof. Tomás Palacios.
MIT researchers developed a super-thin, bendy material that converts WiFi signals into electricity, reports Ian Sample for The Guardian. “In the future, everything is going to be covered with electronic systems and sensors. The question is going to be how do we power them,” says Prof. Tomás Palacios. “This is the missing building block that we need.”
MIT researchers have developed a new app called Perdix that allows users to create 2-D nanostructures using DNA strands, reports Jesus Diaz for Fast Company. Engineers could use Perdix to print nanoscale parts for applications in cell biology, photonics, quantum sensing and computing, Diaz explains.
WCVB-TV’s Mike Wankum visits MIT to learn more about Prof. Nicholas Fang’s work developing a new film that can be coated on windows and can block up to 70 percent of incoming solar heat. Wankum explains that the film “could lead to a future with less need for air conditioning.”
Nature reporter Elizabeth Gibney spotlights Prof. Pablo Jarillo-Herrero’s discovery that graphene can act as a superconductor when twisted to a magic angle. “I haven’t seen this much excitement in the graphene field since its initial discovery,” said ChunNing Jeanie Lau, a professor at Ohio State University, of the impact of Jarillo-Herrero’s findings.
MIT researchers have developed a new technique that can shrink objects to the nanoscale using a laser, reports Lauren Kent for CNN. Kent explains that the technology “could be applied to anything from developing smaller microscope and cell phone lenses to creating tiny robots that improve everyday life.”
Popular Mechanics reporter David Grossman writes about a new fabrication technique developed by MIT researchers that allows for regular-sized objects to be shrunk down to the nanoscale. Grossman explains that the new method, “takes a technique currently used to make images of brain tissue larger and reverses it.”
Inside Science reporter Yuen Yiu writes that MIT researchers have developed a new technique for producing nanoscale structures using a 3-D printing method that shrinks objects. Yiu explains that the new technique operates by “first creating a bigger structure inside of a gel, then shrinking the gel, which brings the structure down to one-thousandth the volume of the original.”
Prof. Pablo Jarillo-Herrero’s discovery that when graphene is rotated to a “magic angle” it can act as a high-temperature superconductor has been named the Physics World 2018 Breakthrough of the Year. Physics World reporter Hamish Johnston writes that the “discovery led to the development of ‘twistronics’, which is a new and very promising technique for adjusting the electronic properties of graphene.”
MIT researchers have developed a new method to shrink 3-D printed objects, reports Douglas Heaven for New Scientist. The technique can be used to create a wide variety of shapes using different materials. “In the 1970s hobbyists built their own computers at home,” explains Prof. Edward Boyden. “Maybe people can now make their own chips.”
MIT researchers have developed a new see-through film that reflects 70 percent of the sun’s incoming heat and could be used to coat a building’s windows, reports the Xinhua news agency. The material, “can cool a building while still letting in a good amount of light, offering an affordable and energy-efficient alternative to existing smart window technologies,” Xinhua explains.
Prof. Michael Strano speaks about his research on carbon-fixing materials, which are “substances powered by the sun that use atmospheric carbon dioxide to grow and repair themselves, just as plants do,” writes Marlene Cimons for Popular Science. “Making a material that can access the abundant carbon all around us is a significant opportunity for materials science,” said Strano.
Researchers from MIT are using the brittle nature of graphene to mass produce cell-sized robots, writes David Grossman of Popular Mechanics. Called “syncells” or synthetic cells, the researchers hope they can be used in biomedical testing. “Inject hundreds into the bloodstreams and let the data fly back into sensors,” explains Grossman.