Amina Khan of The Los Angeles Times examines the first joint detection of gravitational waves by the LIGO and Virgo detectors. Khan notes that the LIGO and Virgo systems are currently being updated to increase their sensitivity to a greater search volume. “There are eight times as many objects in that volume,” explains MIT’s David Shoemaker, LIGO’s spokesperson, increasing the chances of finding gravitational wave sources.
The LIGO and Virgo observatories have made their first joint detection of gravitational waves, report Ben Guarino and Sarah Kaplan for The Washington Post. MIT’s David Shoemaker, spokesperson for LIGO, compared the three-detector network for identifying gravitational waves to a camera tripod that allows scientists to zoom in on the waves' source.
New York Times reporter Dennis Overbye writes that the LIGO and Virgo Scientific Collaborations have together detected gravitational waves from the collision of two black holes. Overbye explains that the new Virgo detector, “greatly increases the network’s ability to triangulate the sources of gravitational waves so that optical telescopes can search for any accompanying fireworks in the visible sky.”
LIGO’s third detection of black holes merging solidifies gravitational wave astronomy as an observational science, writes Amina Khan for The Los Angeles Times. Khan explains that scientists are, “moving LIGO’s work from the examination of singular curiosities to demographic studies of the sky’s invisible denizens."
LIGO scientists have detected a third black hole merger, reports Sophie Bushwick for Popular Science. Bushwick explains that the finding shows that LIGO is, “coming into its own as a black hole telescope: The latest finding proves the existence of a new category of black hole and adds a puzzle piece to the question of how these systems form.”
LIGO scientists have successfully detected two black holes merging for the third time, reports Eric Moskowitz for The Boston Globe. MIT’s David Shoemaker, LIGO’s spokesperson, explains that researchers can use the information gathered by LIGO to get a, “more complete picture of Einstein’s general relativity and the population of these purely relativistic objects we call black holes.”
Writing for The New York Times, Dennis Overbye examines LIGO’s third successful detection of gravitational waves. “We are moving in a substantial way away from novelty towards where we can seriously say we are developing black-hole astronomy,” says David Shoemaker, director of the MIT LIGO Lab and spokesperson for the LIGO Scientific Collaboration.
CBS News reporter William Harwood writes that LIGO scientists have detected the merger of two black holes three billion light years away. David Shoemaker, director of the MIT LIGO Lab and the spokesperson for LIGO, explains that researchers detected, “the merging of black holes roughly 20 and 30 times the mass of our sun.”
MIT’s David Shoemaker, spokesperson for the LIGO Scientific Collaboration, speaks with Doyle Rice of USA Today about LIGO’s third successful detection of gravitational waves. “It is remarkable that humans can put together a story, and test it, for such strange and extreme events that took place billions of years ago and billions of light-years distant from us,” explains Shoemaker.
For the third time, researchers from the LIGO Scientific Collaboration have detected gravitational waves produced by the merger of two black holes, reports Irene Klotz for Reuters. “We’re really moving from novelty to a new observational science,” says MIT's David Shoemaker, spokesperson for the LIGO Scientific Collaboration.
Wall Street Journal reporter Robert Lee Hotz writes that scientists from the Laser Interferometer Gravitational-Wave Observatory (LIGO) have successfully detected two black holes merging for the third time. MIT’s David Shoemaker, spokesperson for the LIGO Scientific Collaboration, explains that the discovery shows, “we are really moving to a new astronomy of gravitational waves.”
MIT researchers have observed a black hole devouring a star, reports Torah Kachur for CBC News. After looking at about a year’s worth of data, researchers found that the “star was getting pulled apart and literally shredded into a debris stream that spiraled around the center of this black hole,” writes Kachur.
Elizabeth Howell writes for Scientific American that a team of researchers, including scientists from MIT, have observed that when a black hole consumes a star there is a burst of electromagnetic activity. Howell explains that the “new research suggests that interactions among the debris could generate the optical and UV emission.”
Calla Cofield writes for Scientific American that a grant will allow the HERA team to search for light from the universe’s first generation of stars. Prof. Jacqueline Hewitt, who is leading the grant, says it’s “remarkable we're designing instruments so we can detect what was happening 13 billion years ago.”
MIT researchers have observed a black hole devouring a star almost 300 million light years away, writes Andy Rosen for The Boston Globe. “We are actually mapping out in real time what is happening as the star is getting ripped [apart] and it’s falling onto the black hole,” says postdoctoral fellow Dheeraj Pasham.