The discovery of the oldest and most distant black hole ever observed could provide scientists with insights into the early stages of our universe, reports Will Dunham for Reuters. “This object provides us with a measurement of the time at which the universe first became illuminated with starlight,” explains Prof. Robert Simcoe.
NPR’s Nell Greenfieldboyce reports that scientists have discovered the most distant supermassive black hole every discovered, and that the findings are shedding light on when starlight first appeared in our universe. "We have an estimate now, with about 1 to 2 percent accuracy, for the moment at which starlight first illuminated the universe,” explains Prof. Robert Simcoe.
USA Today reporter Doyle Rice writes that a team of astronomers, including several from MIT, has discovered the oldest and most distant supermassive black hole ever detected. “The black hole resides in a quasar and its light reaches us from when the universe was only 5% of its current age — over 13 billion years ago,” explains Rice.
Prof. Nergis Mavalvala speaks with Massive reporter Prabarna Ganguly about her work engineering high-precision laser beams to detect signals from deep space, the long hunt for gravitational waves and her hopes for future generations of scientists. Ganguly writes that Mavalvala is, “one of the stalwarts in a long, arduous, and deeply human discovery of faraway perturbations rippling through the universe.”
UPI reporter Brooks Hays writes that an international team of astronomers, including MIT Prof. Saul Rappaport, has detected comets outside the Milky Way. “The distant ice balls, roughly the size of Halley's Comet, were spotted orbiting a small star 800 light-years from Earth. They were documented using transit photometry,” Hays explains.
Wired reporter Abigail Beall explores the science behind the successful detection of two colliding neutron stars. "It immediately appeared to us the source was likely to be neutron stars, the other coveted source we were hoping to see—and promising the world we would see," says MIT’s David Shoemaker, spokesperson for the LIGO Scientific Collaboration.
Boston Globe reporter Eric Moskowitz explores the significance of the first detection of two colliding neutron stars using gravitational wave detectors and telescopes. Moskowitz notes that the discovery offers, “so many immediate and long-term rewards that researchers struggled to pick their favorite part.” Senior Research Scientist Erik Katsavounidis explained that, “It’s like getting a kid in the candy store and telling them to choose.”
Boston Herald reporter Marie Szaniszlo writes about how the first successful detection of gravitational waves and light emitted from the collusion of two neutron stars has provided insight into gamma rays and heavy elements. Prof. Anna Frebel explains that, “What makes this such an important discovery is that we can actually see element formation in action.”
Channel 7’s Matt Rascon reports on how scientists from LIGO, Virgo and 70 observatories around the world have detected gravitational waves and light emitted from two colliding neutron stars. “For the first time we’re able to put it all together and get a much more complete picture of what nature is doing,” explains Prof. Nergis Mavalvala.
AFP reporter Mariëtte Le Roux writes about how the detection of two colliding neutron stars has provided scientists with new insights into the universe. "It was clear to us within minutes that we had a binary neutron star detection," said MIT’s David Shoemaker, spokesperson for the LIGO Scientific Collaboration. "The signals were much too beautiful to be anything but that.”
Washington Post reporters Ben Guarino and Sarah Kaplan delve into the first detection of a kilonova using both gravitational wave detectors and telescopes. “It's a monumental thing, a testimony to a lot of people working together,” explains David Shoemaker, a senior research scientist at MIT and spokesperson for the LIGO Scientific Collaboration.
Wall Street Journal reporter Robert Lee Hotz writes that scientists have detected colliding neutron stars and found that the smashups are the source of gold and other heavy elements found throughout the universe. “The neutrons can condense down into the heavy elements—gold, platinum and others—that make pretty jewelry so pretty,” explains MIT’s David Shoemaker.
MIT’s David Shoemaker, spokesperson for the LIGO Scientific Collaboration, speaks with NPR’s Nell Greenfieldboyce about the first detection of colliding neutron stars. Shoemaker recalls the excitement of the discovery, “as we tried to figure out how we could most quickly get the news out to observers to try and make the most of this event."
Researchers from the LIGO, Virgo and 70 additional observatories around the world have detected gravitational waves and light from the collision of two neutron stars, reports Dennis Overbye for The New York Times. MIT’s David Shoemaker, the spokesperson for the LIGO Scientific Collaboration, described the event as, “joy for all.”
WBUR’s Bruce Gellerman profiles Nobel laureate Prof. Emeritus Rainer Weiss, noting that his “stories of accomplishments and failure are legendary at MIT.” Prof. Peter Fisher, head of the Physics Department, says that Weiss, "is a tremendously intelligent man, but he’s got more perseverance, I think, than anyone else.”