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.

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.”

Andrea Ghez ’87 speaks with Carol Stabile of Ms. magazine about the importance of representation in encouraging more women and people of color to pursue careers in STEM fields. Ghez recalls how her science teacher in high school encouraged her to apply to MIT, describing the experience as “'a lovely early lesson in how to persevere,’ that helped her to develop what she described as the muscle to persevere, and to turn problems into opportunities to grow and learn.”

CBS Boston spotlights how Andrea Ghez ’87 has been awarded the 2020 Nobel Prize in Physics for her work discovering a supermassive black hole at the center of our galaxy. “It really represents the basic research - you don’t always know how it is going to affect our lives here on Earth, but it is pushing the frontier of our knowledge forward," says Ghez, "both from the point of view of pure physics (understanding what a black hole is), and then also their astrophysical world in the formation and evolution of galaxies.”

Andrea Ghez ’87 has been selected as one of the winners of this year’s Nobel Prize in Physics for her work advancing our understanding of black holes. "Black holes, because they are so hard to understand, is what makes them so appealing,'' says Ghez. “I really think of science as a big, giant puzzle.”

Astronomers have found that the M87* black hole appears to be wobbling, reports Sophie Lewis for CBS News. “The wobbling is big news — it allows scientists to study the object's accretion flow,” writes Lewis. “Studying that region is key to understanding how the black hole and surrounding matter interact with the host galaxy.”

Gizmodo reporter George Dvorsky writes that astronomers from the Event Horizon Telescope collaboration, including MIT Haystack Observatory researchers, have studied the physical changes to M87* black hole and found that it appears to be wobbling. “With this paper, we’ve now entered into a new era of studying the intimate areas around black holes,” writes Dvorsky.

Boston 25 spotlights how scientists from LIGO and Virgo have detected what may be the most massive black hole collision yet. “The result of the black holes colliding created the first-ever observed intermediate black hole, at 142 times the mass of the sun,” reports Boston 25.

Scientists from LIGO and Virgo have detected the largest collision between two black holes to date, which appears to have created an “intermediate-mass” black hole, reports Loren Grush for The Verge. Intermediate-mass black holes, “are really the missing link between [black holes with] tens of solar masses and millions,” says Prof. Salvatore Vitale. “It was always a bit baffling that people couldn’t find anything in between.”

Gizmodo reporter George Dvorsky writes about how researchers from MIT and other institutions have detected the corona of a supermassive black hole disappearing and then reappearing. Dvorsky writes that their findings suggest this “strange episode was caused by a runaway star.”

Popular Science names “Advanced LIGO by MIT and CalTech (2016)” as one of the 20 best tech discoveries of the last decade. “LIGO has captivated people the world over, making them curious about esoteric subjects like the nature of space and origin of, well, everything.”

Boston Globe reporter Laura Krantz visits MIT’s Haystack Observatory to learn more about the place where scientists played a key role in developing the first image of a black hole and created a supercomputer used to compile the image. Krantz notes that researchers at Haystack also study the Earth, not-far-away planets, and stars, and are creating devices to track the decay of icebergs.

Sky and Telescope editor Monica Young speaks with WBUR about how scientists from the LIGO and Virgo gravitational wave observatories, including MIT researchers, may have detected a black hole colliding with a neutron star. Young explains that upgrades made to both observatories should enable investigation of not only individual cosmic events, but also the study of neutron stars and black holes as populations.