CNN reporter Ashley Strickland writes about how researchers from the CHIME collaboration have announced that they have detected over 500 fast radio bursts (FRBs) using a radio telescope in Canada. "With all these sources, we can really start getting a picture of what FRBs look like as a whole, what astrophysics might be driving these events, and how they can be used to study the universe going forward," explains graduate student Kaitlyn Shin.
Scientists from the CHIME Collaboration, including MIT researchers, have reported that the radio telescope has detected more than 500 fast radio bursts in its first year of operation, reports Davide Castelvecchi for Nature. The findings suggest that these events come in two distinct types. “I think this really just nails it that there is a difference,” says Prof. Kiyoshi Masui.
The CHIME radio telescope has catalogues more than 500 fast radio bursts (FRBs), which could be used to help map the universe, reports Charlie McKenna for The Boston Globe. FRBs are “kind of like lighthouses or sonar pings,” explains graduate student Calvin Leung, “and for the very first time we’ve shown that we can detect them in large enough quantities that you can really use them to make statements like, ‘Oh, the universe is expanding at this rate,’ or ‘This is how much matter there is in the whole universe.’”
Inverse reporter Passant Rabie explores how the CHIME radio telescope has identified more than 500 fast radio bursts in its first year of operation, providing clues as to the structure of the universe. “With enough of them, they are going to be the ultimate tool for mapping the universe,” says Prof. Kiyoshi Masui.
Axios reporter Miriam Kramer writes that a new study co-authored by MIT researchers suggests that all black holes go through a similar cycle when feeding, whether they are big or small. “Black holes are some of the most extreme objects found in our universe,” writes Kramer. “By studying the way they grow, scientists should be able to piece together more about how they work.”
Boston Globe reporter Charlie McKenna writes that a new study co-authored by MIT researchers finds that the way black holes evolve as they consume material is the same, no matter their size. “What we’re demonstrating is, if you look at the properties of a supermassive black hole in the cycle, those properties are very much like a stellar-mass black hole,” says research scientist Dheeraj “DJ” Pasham. The findings mean “black holes are simple, and elegant in a sense.”
Academic Times reporter Monisha Ravisetti writes that a new study by physicists from a number of institutions, including MIT, finds that supermassive black holes devour gas just like their smaller counterparts. “This is demonstrating that, essentially, all black holes behave the same way,” says research scientist Dheeraj “DJ” Pasham. “It doesn’t matter if it’s a 10 solar mass black hole or a 50 million solar mass black hole – they appear to be acting the same way when you throw a ball of gas at it.”
New Scientist reporter Leah Crane writes that researchers from the LIGO and Virgo gravitational wave observatories have potentially detected primordial black holes that formed in the early days of the universe. “When I started this, I was expecting that we would not find any significant level of support for primordial black holes, and instead I got surprised,” says Prof. Salvatore Vitale.
Professor Martin Bazant and Professor John Bush have developed a new safety guideline to limit the risk of airborne Covid-19 transmission in different indoor settings. “For airborne transmission, social distancing in indoor spaces is not enough, and may provide a false sense of security,” says Bazant. “Efficient mask use is the most effective safety measure, followed by room ventilation, then filtration,” adds Bush.
CNN reporter Maggie Fox writes that MIT researchers have developed a new formula for calculating the risk of airborne Covid-19 transmission in indoor settings. "To minimize risk of infection, one should avoid spending extended periods in highly populated areas. One is safer in rooms with large volume and high ventilation rates," write Profs. Martin Bazant and John Bush.
Boston Globe reporter Charlie McKenna writes that MIT researchers have used the spin of black holes detected by the LIGO and Virgo detectors to search for dark matter. "In reality, there is a much broader set of theories that predict or relies on the existence of these very ultra-light particles,” says Prof. Salvatore Vitale. “One is dark matter. So they could be dark matter. But they could also solve other open problems in particle physics.”
A new study by MIT researches finds that some masses of boson particles don’t actually exist, reports Monisha Ravisetti for The Academic Times. “[Bosons] could be dark matter particles, or they could be something that people call axions, which are proposed particles that could solve problems with the magnetic bipoles of particles,” says Prof. Salvatore Vitale. “Because they can be any of these things, that means they could also have an incredibly broad range of masses.”
Prof. Robert Jaffe speaks with CNN reporter Stephanie Bailey for a piece that explores how the rivalry between Edison, Tesla and Westinghouse helped lead to transformations in the development of electricity. Bailey also features alumnus Joel Jean and his solar tech startup.
New Scientist reporter Layal Liverpool writes that a new study co-authored by MIT researchers finds that “synthetic cells made by combining components of Mycoplasma bacteria with a chemically synthesised genome can grow and divide into cells of uniform shape and size, just like most natural bacterial cells.”
Writing for The Boston Globe, M.J. Andersen highlights Prof. Sara Seager’s book, “The Smallest Lights in the Universe.” Seager’s memoir is "half hymn to the stars and half guide to grief recovery,” writes Andersen. “Lured by her faith in finding life elsewhere, she continued her research on exoplanets — versions of other star-orbiting Earths — and methods for detecting them.”