MIT researchers have developed a cost-effective, cell analysis method using graphene sheets, reports Brooks Hays for UPI. The new technique could allow “simple sheets of graphene oxide to function as a diagnostics device for medical and biological tests,” Hays explains.
NPR reporter Colin Dwyer writes about the life and work of Institute Professor Emerita Mildred Dresselhaus, who died at 86. Dwyer writes that “during her celebrated career, she sought to prepare a path for potential successors — the female scientists whom she mentored and opened doors for across decades.”
Institute Prof. Emerita Mildred Dresselhaus, known for her work deciphering the secrets of carbon, died at 86, reports Bryan Marquard for The Boston Globe. Dresselhaus’ granddaughter Leora Cooper, an MIT graduate student, explained that by being a role model for women in STEM, “she encouraged me to not just see the changes that needed to be made, but to start making them.”
New York Times reporter Natalie Angier memorializes the life and work of Institute Professor Emerita Mildred Dresselhaus, affectionately nicknamed the “Queen of Carbon” for her pioneering research into the fundamental properties of carbon. Angier notes that Dresselhaus was also “renowned for her efforts to promote the cause of women in science.”
Institute Professor Emerita Mildred Dresselhaus, who was known as the “queen of carbon science” and was an advocate for women in STEM, died at 86, reports Mark Anderson for IEEE Spectrum. Dresselhaus “pioneered the study of carbon nanostructures at a time when studying physical and material properties of commonplace atoms like carbon was out of favor.”
Researchers at MIT have designed a new living material infused with cells that could one day be used as a wearable sensor, writes Brooks Hays for UPI. The researchers used the new material to “design gloves and bandages that light up when they come in contact with target chemicals.”
MIT researchers have created a new strong, yet lightweight material by using a 3-D printer to fuse flakes of graphene into a sponge-like object, reports Nick Kwek for BBC News. “The newfangled product could be used in the construction of airplanes or buildings,” says Kwek.
MIT researchers have used computer models to turn flakes of graphene into 3-D structures, creating one of lightest, strongest materials, writes Nicola Davison for CNN. "Once they combine and fuse together, all the flakes contribute to the strength of the overall structure," research scientist Zhao Qin explains.
Researchers at MIT have fused flakes of graphene into a sponge-like shape, creating one of the strongest lightweight materials, writes James Temperton for Wired. Flakes of graphene were compressed using heat and pressure, then 3-D printers were used to create a “strong, stable structure similar to some corals” for stress tests.
MIT researchers have developed a new ultra-light material that is ten times stronger than steel, reports Tia Ghose for CBS News. Ghose explains that in the future, the material could potentially be used to build bridges, “which would be ultrastrong, lightweight, and insulated against heat and cold because of all the myriad air pockets in the material.”
By fusing graphene into a porous 3-D form, MIT researchers have created a strong, lightweight material, writes Brooks Hays for UPI. “The findings suggest a 3D material's tensile and compressive properties are dependent on the geometry of its structure, not the strength of the 2D material from which it is derived,” explains Hays.
MIT researchers have designed a strong, lightweight material that is ten times stronger than steel, reports Katharine Schwab for Co.Design. “If we can produce the material in big amounts, we can use that to somehow substitute some of the steel used for construction,” says research scientist Zhao Qin.
Prof. Donald Sadoway speaks with Tom Ashbrook of NPR’s On Point about potential alternatives for lithium-ion batteries. “If we could make a battery based on aluminum we’d have something that is powerful, safe, and cheap,” says Sadoway.
MIT researchers have developed a stretchy, biocompatible material that could be implanted in a patient’s body and used to stimulate cells or detect disease, according to FOX News. The hydrogel “could bend and twist in a patient’s body without breaking down.”
CBC reporter Nora Young explores how MIT researchers have developed a new material, inspired by beaver fur, that could help keep surfers warm. “In sports technology there's a great need for textiles that have great insulating properties in water, but still let you stay agile and nimble,” explains graduate student Alice Nasto.