Latest news with #LIGO
CTV News
12 hours ago
- Science
- CTV News
‘Where do we come from?': U of M researchers help detect record-breaking black hole collision
CTV's Harrison Shin has more on the black hole discovery made by two University of Manitoba researchers. Two University of Manitoba researchers are exploring the cosmos with one philosophical question in mind. Dr. Samar Safi-Harb and postdoctoral fellow Nathan Steinle are part of a team using the Laser Interferometer Gravitational-Wave Observatory (LIGO), a facility capable of detecting gravitational waves. 'Not everything in the universe can be seen with light, and gravitational waves are a new way of looking at the universe. These are ripples in the fabric of space-time,' Safi-Harb said. LIGO recently detected a collision between two black holes — an event that stands out for its scale. 'It's the most massive black hole merger detected by LIGO. And by 'most massive,' I mean each of these black holes is more than 100 times the mass of the sun,' she said. Until now, black holes of this size had not been directly observed. LIGO's detection provides the first direct evidence of their existence, according to Safi-Harb. Steinle said the discovery raises fundamental questions. 'It's so important because we're not sure if there's an upper limit on the mass. Can it keep getting bigger and bigger until we all grow old?' he said. He added that the finding is just the beginning. 'It really gives you great hope. Once future detectors are built — and they'll have at least 10 times better sensitivity — we'll be able to do a lot more,' he said. For Safi-Harb, the discovery brings scientists one step closer to understanding the universe. 'Finding these extreme events — whether through light, gravitational waves or other cosmic messengers — really brings us a bit closer to understanding our cosmic origins,' she said.
The Hindu
a day ago
- Science
- The Hindu
New gravitational waves reveal black hole with ‘forbidden' mass
Scientists working with a network of observatories located around the world recently reported that they had detected a powerful and unusual burst of gravitational waves, which they called GW231123. The signal was traced back to two black holes colliding into each other on November 23, 2023. This isn't the first time the observatories have detected gravitational waves, but the event is special because of the extraordinary size of the black holes involved: they are much heavier than most seen before. More interesting is the fact that the heavier black hole appeared to have a 'forbidden' mass — a value inside a range called the pair instability mass gap — which challenges what physicists thought was possible for black holes created from dying stars. Imagine a massive star at the end of its life. Usually, very heavy stars explode in supernovae, leaving behind black holes. But theory predicts that no black holes should form with masses between about 60 and 130 times the mass of our sun. This is the pair instability mass gap: it's thought to exist because stars this large explode so violently that nothing remains, not even a black hole, just scattered gas. Above 130 solar masses, stars may skip the explosion and directly collapse to create supermassive black holes. So finding black holes in the mass gap raises important questions about how they got there. On November 23, 2023, the two Laser Interferometer Gravitational-wave Observatories (LIGO) in the U.S. detected a burst of gravitational waves, faint ripples in spacetime created by massive objects accelerating and colliding. The GW231123 event lasted only about one-tenth of a second and the signal was strong and clear. The collision happened about 2 billion lightyears away. Scientists at the LIGO as well as Virgo and KAGRA observatories in Italy and Japan, respectively, conducted a detailed analysis and determined the pre-merger mass of the two colliding black holes. The heavier one had 120-159 solar masses but likely centred at 137 solar masses. The lighter one weighed 51-123 solar masses but likely centred at 103 solar masses. The total mass involved in the collision was thus likely 190-265 solar masses, rendering GW231123 the most massive black hole merger ever seen with high confidence. The mass of the heavier black hole in the merger is right inside, or just above, the pair instability mass gap. The mass of the lighter one could also be in or near the gap, given the large uncertainty. According to theory, stars can't leave behind black holes in this range, so the scientists figure something else must be going on. They are already considering several explanations. One, for example, is called a hierarchical merger: smaller black holes could merge inside dense star clusters, then the resulting larger black holes merge again, building up over time and ending up inside the gap. This possibility finds some support from the fact that both black holes were spinning rapidly. Usually, black holes formed from individual stars aren't spinning this fast. Another possibility is a stellar merger. Sometimes, two stars might merge before they die, creating a much larger star that might collapse to form a black hole whose mass lands inside the gap. It's also possible these two black holes formed right after the Big Bang, by a process unrelated to stars, although this idea is in the realm of speculation. Yet other potential explanations include some stars losing less mass before exploding or hitherto entirely unknown processes. The main idea is that the detection of GW231123 suggests the universe can make black holes in the mass gap after all, and not just through the collapse of single stars. And that this fact means scientists' theories about the lives and deaths of massive stars need updating.
Yahoo
2 days ago
- Science
- Yahoo
Scientists record a black hole collision they weren't sure was possible
A pair of newly-discovered record-breaking black holes has scientists simultaneously popping the champagne and scratching their heads. The massive duo are the largest ever recorded at the Laser Interferometer Gravitational-Wave Observatory (LIGO), which was built to detect ripples in the fabric of spacetime caused by the collisions of massive objects. These enormous outliers are challenging theorists to figure out just how they grew to such titanic sizes. 'We don't think black holes form between about 60 and 130 times the mass of the sun, and these two seem to be pretty much slap bang in the middle of that range,' says Mark Hannam, a physicist at Cardiff University in the UK and a LIGO team member. Your normal everyday black hole is thought to be born during the death of a giant star, when the star's weighty core collapses down into an infinitesimal point with such strong gravity that nothing, not even light, can escape it. But the physics of this process gets wonky for especially huge stars. Once their cores weight more than around 60 solar masses, the collapse becomes so violent that the entire star is blown to smithereens, leaving nothing, not even a black hole, behind. Yet LIGO is now spotting more and more black holes within this 'forbidden' zone, including the newest behemoths. They are thought to be 103 and 137 times the sun's mass, according to a paper posted July 13 to but each has enough uncertainty in their measured properties that they could both be inside the prohibited range. When they met and merged out in the deep dark universe billions of years ago, they created an even larger monster tipping the scales at between 190 and 265 solar masses, the most massive beast LIGO has ever seen. As the observatory captures gravitational waves from more such events, researchers will be able to tease apart the mystery of their creation and perhaps learn whether they have a connection to the astoundingly huge black holes lurking in the centers of galaxies. Black holes were thought to come in two flavors. This discovery is a strange third For a long time, black holes were known to come in just two versions—approximately sun-sized and galactic. Most of the roughly 300 black holes LIGO has detected so far fit into the first category: They are between a few and several tens of times the sun's mass and are believed to have formed after a gargantuan star exploded as a supernova, leaving behind a dense remnant that inexorably sucks in anything that gets too close. The second version is a much more gargantuan beast. Telescopes have spotted black holes in the centers of nearly every galaxy; gravitational monstrosities weighing 100 million solar masses or more that appear to regulate star formation within these galaxies. Nobody is quite sure how these immense devourers got so big. Did they start out as sun-scale black holes and then somehow grow to extreme size? Or was there another story behind their creation? The existence of black holes in the intermediate range—somewhere between 100 and 100,000 times the sun's mass—would help bridge this gap and perhaps help explain whether small black holes were turning into larger ones. But, until recently, physicists had never seen one. To great fanfare in 2020, LIGO researchers announced that they'd found a black hole duo with masses 66 and 85 times that of the sun, whose smash-up produced a giant with around 150 solar masses. The finding for the first time showed that black holes could cross into this threshold of intermediate mass, though theorists are still debating exactly how that happened. The problem is that when a gigantic star has a core that weights between 60 and 130 times the sun's mass, it can reach blazing temperatures nearing 300 million degrees Celsius during the end of its life. At that point, particles of light spontaneously transform into electrons and their antimatter counterparts, positrons. These particles can no longer hold up the star's heavy outer layers, which come crashing down with such ferocity that the core is completely obliterated. No black hole, or anything else, results. Physicists have speculated about a few possibilities to explain what they're seeing with LIGO. For one, their theories of stellar evolution might be wrong and perhaps something can survive the severe core collapse of humongous stars. The other possibilities involve smaller black holes growing into larger ones via some kind of two-step process, says astrophysicist Priyamvada Natarajan of Yale University in Connecticut. It could be either that two star-sized black holes came together and combined to form heavier behemoths or a small black hole was created and then sucked down gas and dust to balloon into a more massive beast. 'The question is: What are the cosmic environments and conditions where such things can happen?' Natarajan asks. One major clue might lie with the two new objects, which are spinning around like a top at close to the upper limit that scientists think they can spin. They have the fastest rotations of any black hole LIGO has ever seen. Some researchers have posited such spins could arise when smaller black holes meet, merge, and spin each other up. But Natarajan thinks perhaps something else is going on here. Because if the colliding black holes were spinning in opposite directions (and there's a good chance they were) the merger black hole would have produced a slower-spinning object. She favors the idea that smaller black holes were born in dense stellar clusters full of gas and dust. As that star-sized black hole bounced around inhaling material like water going down a drain, it could have grown and spun up to the extreme rotation seen in the new objects. She and her colleagues are working to calculate the exact outcome of such a feasting process in stellar clusters. Scientists aren't done searching for enormous black holes Future upgrades to the LIGO detectors will make them more sensitive, letting them uncover even more enormous black holes and measure their properties more precisely. Along with gravitational wave detectors in Europe, Japan, and eventually India, researchers will be able to pinpoint black hole events better on the night sky, allowing telescopes to scope those areas out and see if there's, for instance, a dense star cluster that might favor one formation mechanism or another. Researchers are also looking forward to instruments such as the Cosmic Explorer and Einstein Telescope, expected to be operational in the mid-2030s or 40s, which will be able to see black hole mergers that occurred much earlier in the universe's history. Such gravitational wave observatories might be able to capture events when galaxies were first forming, potentially providing insights into how their central black holes became so gargantuan, along with better data on small and intermediate black holes. 'There's just so many black holes littered in the universe,' says Natarajan. 'The fact that we're starting to bridge these scales, I think that's super exciting.' 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Time of India
2 days ago
- Science
- Time of India
Scientists discover the most massive crash of two black holes, each bigger than 100 Suns
The outer space has been home to mysterious, invisible giants with the power to bend space and time called Black holes. But recently, astronomers detected something so unique that it's forcing experts to rethink what we know about how black holes form and evolve. The discovery includes two black holes, whose size is more massive than 100 suns, crashing into one another in a collision that sent ripples through the fabric of space-time. In fact, the mass and spin of the black holes don't match what current models predict. This has given rise to new questions and possibilities about the life and growth of these cosmic powerhouses. The largest recorded black hole merger is a massive event named GW231123. Detected by the LIGO observatories in the US, along with partner detectors Virgo in Italy and KAGRA in Japan, this event involved two massive black holes, weighing roughly 100 and 140 times the mass of the sun. When they collided, they sent faint ripples through space-time called gravitational waves , a phenomenon first predicted by Einstein in 1915. 'These amazing detectors are really the most sensitive measuring instruments that human beings have ever built,' said Mark Hannam, head of the Gravity Exploration Institute at Cardiff University and a member of the LIGO Scientific Collaboration. 'We're observing the most violent and extreme events in the universe through the smallest measurements we can make.' Something that sets this event apart is the size and speed of the black holes involved. by Taboola by Taboola Sponsored Links Sponsored Links Promoted Links Promoted Links You May Like Die intelligentere Art, Ihre Anlageziele zu erreichen eToro Learn More Undo 'The individual black holes are special because they lie in a range of masses where we do not expect them to be produced from dying stars,' said Charlie Hoy, research fellow at the University of Plymouth and also part of the LIGO collaboration. This unusual mass range is known as the 'mass gap', meaning a theoretical range between about 60 and 130 solar masses where traditional star death isn't expected to create black holes. According to Hannam, 'There's a range of masses where we think that it's not possible for black holes to form that way. And the black holes from GW231123 live bang in the middle of that gap.' To explain this, researchers believe these black holes may be the result of earlier black hole mergers, which could essentially be a cosmic chain reaction. 'You can have this process where you just build up more and more massive black holes,' Hannam explained. Supporting this theory is the fact that the black holes appeared to be spinning near their physical limits. 'So far, most black holes we have found with gravitational waves have been spinning fairly slowly,' Hoy noted. 'This suggests that GW231123 may have formed through a different mechanism… or it could be a sign that our models need to change.' 'This new merger is very hard to explain in other ways,' said Zoltan Haiman, professor at the Institute of Science and Technology Austria, suggesting that these may be remnants of multiple generations of black hole mergers. Going ahead, future detections could reveal whether this record-breaking collision was a rare one-off or a clue to a much larger population of heavyweight black holes hiding in the universe.
National Geographic
2 days ago
- Science
- National Geographic
Scientists record a black hole collision they weren't sure was possible
The largest black hole collision ever recorded has scientists' jaws on the floor — and scratching their heads. This computer-simulated image shows a supermassive black hole at the core of a galaxy. Image by NASA, ESA, and D. Coe, J. Anderson, and R. van der Marel (STScI) A pair of newly-discovered record-breaking black holes has scientists simultaneously popping the champagne and scratching their heads. The massive duo are the largest ever recorded at the Laser Interferometer Gravitational-Wave Observatory (LIGO), which was built to detect ripples in the fabric of spacetime caused by the collisions of massive objects. These enormous outliers are challenging theorists to figure out just how they grew to such titanic sizes. 'We don't think black holes form between about 60 and 130 times the mass of the sun, and these two seem to be pretty much slap bang in the middle of that range,' says Mark Hannam, a physicist at Cardiff University in the UK and a LIGO team member. Your normal everyday black hole is thought to be born during the death of a giant star, when the star's weighty core collapses down into an infinitesimal point with such strong gravity that nothing, not even light, can escape it. But the physics of this process gets wonky for especially huge stars. Once their cores weight more than around 60 solar masses, the collapse becomes so violent that the entire star is blown to smithereens, leaving nothing, not even a black hole, behind. Yet LIGO is now spotting more and more black holes within this 'forbidden' zone, including the newest behemoths. They are thought to be 103 and 137 times the sun's mass, according to a paper posted July 13 to but each has enough uncertainty in their measured properties that they could both be inside the prohibited range. When they met and merged out in the deep dark universe billions of years ago, they created an even larger monster tipping the scales at between 190 and 265 solar masses, the most massive beast LIGO has ever seen. As the observatory captures gravitational waves from more such events, researchers will be able to tease apart the mystery of their creation and perhaps learn whether they have a connection to the astoundingly huge black holes lurking in the centers of galaxies. Black holes were thought to come in two flavors. This discovery is a strange third For a long time, black holes were known to come in just two versions—approximately sun-sized and galactic. Most of the roughly 300 black holes LIGO has detected so far fit into the first category: They are between a few and several tens of times the sun's mass and are believed to have formed after a gargantuan star exploded as a supernova, leaving behind a dense remnant that inexorably sucks in anything that gets too close. The second version is a much more gargantuan beast. Telescopes have spotted black holes in the centers of nearly every galaxy; gravitational monstrosities weighing 100 million solar masses or more that appear to regulate star formation within these galaxies. Nobody is quite sure how these immense devourers got so big. Did they start out as sun-scale black holes and then somehow grow to extreme size? Or was there another story behind their creation? The existence of black holes in the intermediate range—somewhere between 100 and 100,000 times the sun's mass—would help bridge this gap and perhaps help explain whether small black holes were turning into larger ones. But, until recently, physicists had never seen one. To great fanfare in 2020, LIGO researchers announced that they'd found a black hole duo with masses 66 and 85 times that of the sun, whose smash-up produced a giant with around 150 solar masses. The finding for the first time showed that black holes could cross into this threshold of intermediate mass, though theorists are still debating exactly how that happened. The problem is that when a gigantic star has a core that weights between 60 and 130 times the sun's mass, it can reach blazing temperatures nearing 300 million degrees Celsius during the end of its life. At that point, particles of light spontaneously transform into electrons and their antimatter counterparts, positrons. These particles can no longer hold up the star's heavy outer layers, which come crashing down with such ferocity that the core is completely obliterated. No black hole, or anything else, results. Physicists have speculated about a few possibilities to explain what they're seeing with LIGO. For one, their theories of stellar evolution might be wrong and perhaps something can survive the severe core collapse of humongous stars. The other possibilities involve smaller black holes growing into larger ones via some kind of two-step process, says astrophysicist Priyamvada Natarajan of Yale University in Connecticut. It could be either that two star-sized black holes came together and combined to form heavier behemoths or a small black hole was created and then sucked down gas and dust to balloon into a more massive beast. 'The question is: What are the cosmic environments and conditions where such things can happen?' Natarajan asks. One major clue might lie with the two new objects, which are spinning around like a top at close to the upper limit that scientists think they can spin. They have the fastest rotations of any black hole LIGO has ever seen. Some researchers have posited such spins could arise when smaller black holes meet, merge, and spin each other up. But Natarajan thinks perhaps something else is going on here. Because if the colliding black holes were spinning in opposite directions (and there's a good chance they were) the merger black hole would have produced a slower-spinning object. She favors the idea that smaller black holes were born in dense stellar clusters full of gas and dust. As that star-sized black hole bounced around inhaling material like water going down a drain, it could have grown and spun up to the extreme rotation seen in the new objects. She and her colleagues are working to calculate the exact outcome of such a feasting process in stellar clusters. Scientists aren't done searching for enormous black holes Future upgrades to the LIGO detectors will make them more sensitive, letting them uncover even more enormous black holes and measure their properties more precisely. Along with gravitational wave detectors in Europe, Japan, and eventually India, researchers will be able to pinpoint black hole events better on the night sky, allowing telescopes to scope those areas out and see if there's, for instance, a dense star cluster that might favor one formation mechanism or another. Researchers are also looking forward to instruments such as the Cosmic Explorer and Einstein Telescope, expected to be operational in the mid-2030s or 40s, which will be able to see black hole mergers that occurred much earlier in the universe's history. Such gravitational wave observatories might be able to capture events when galaxies were first forming, potentially providing insights into how their central black holes became so gargantuan, along with better data on small and intermediate black holes. 'There's just so many black holes littered in the universe,' says Natarajan. 'The fact that we're starting to bridge these scales, I think that's super exciting.'
