In an article for Salon about extreme weather, Paul Rosenberg highlights a new study by MIT researchers that shows climate change could cause California to “experience three more extreme precipitation events per year by 2100, although the number could be reduced by half that if aggressive policy measures are pursued.”
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.
Writing for Forbes, Eric Mack highlights a study by MIT researchers that shows extreme precipitation events in California should become more frequent due to climate change. The researchers found that by 2100, California “should expect between one and three more extreme precipitation events…every single year.”
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.
A study by MIT researchers provides evidence that California could see an increase in extreme precipitation events due to climate change, according to CBS San Francisco. “Using large scale future projections and factoring in policies to restrict global warming, researchers said the Bay Area could see more of those kinds of storms on a seasonal basis.”
UPI reporter Brooks Hays writes that MIT researchers have developed a new model that helps predict the frequency of extreme precipitation events. The researchers found that “a rise in global temperature of 4 degrees Celsius will yield an extra three extreme precipitation events per year in California by the end of the century.”
Brian Sullivan writes for Bloomberg about research affiliate Judah Cohen’s “Siberian Snow Theory,” which is based on the concept that the amount of snow covering the ground in northern Eurasia can be used to predict how cold winter will be in the northern hemisphere. Sullivan writes that Cohen “spies all the makings of an early, cold winter,” this year.
Writing for The Washington Post, Prof. Jessika Trancik examines how federal policy could impact global progress on responding to climate change. “We estimate that the U.S. can achieve the majority share of its original 2025 emissions reduction target even with federal policy changes,” Trancik explains.
MIT has been named the top university in the world in the latest QS World University Rankings, reports Nick Morrison for Forbes. This is the fifth consecutive year that MIT has earned the number one spot in the QS rankings.
ABC News reporter Gillian Mohney writes that Prof. Lydia Bourouiba has captured footage of a person sneezing, showing how far sneeze droplets can travel. Bourouiba found that “large droplets tended to land within 1 to 2 meters (about 3 to 6 feet) and that small droplets could get as far as 6 to 8 meters away (19 to 26 feet).”
Prof. Lydia Bourouiba has published a new slow-motion video of a person sneezing as part of her research into how sneezes spread disease, reports Rae Ellen Bichell for NPR. Bichell explains that Bourouiba’s research is aimed at better understanding “how to prevent microbes from moving from a sick person or contaminated surface to somebody else.”