Clearest Black hole collision confirms predictions by Einstein and Hawking
Astronomers have detected a collision between two black holes in unprecedented detail, offering the clearest view yet into the nature of these cosmic oddities and confirming long-held predictions made by legendary physicists Albert Einstein and Stephen Hawking. The event, dubbed GW250114, became known when researchers spotted it with the Laser Interferometer Gravitational-Wave Observatory (LIGO), a set of two identical instruments located in Livingston, Louisiana, and Hanford, Washington. The instruments detected gravitational waves, faint ripples in space-time produced by the two black holes slamming into each other. A record-breaking gravitational wave from two merging black holes has given scientists their most detailed test yet of Einstein’s theory of gravity. The sharpest black hole collision ever detected just gave Einstein another win, and raised hopes that the next one might rewrite gravity. For scientists who follow gravitational waves as they arrive from deep space, GW250114 stands out as an extraordinary event. It is the most precise gravitational wave signal ever captured from a pair of merging black holes, offering researchers a rare chance to closely examine Albert Einstein’s theory of gravity, known as general relativity. Its clarity allowed scientists to measure multiple “tones” from the collision, all matching Einstein’s predictions. The confirmation is exciting, but so is the possibility that future signals won’t behave so neatly. Any deviation could point to new physics beyond our current understanding of gravity.
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Searching for gravitational waves, phenomena predicted in 1915 as part of Einstein’s theory of relativity, is the only way to identify black hole collisions from Earth. Einstein believed that the waves would be too weak to ever be picked up by human technology, but in September 2015, LIGO recorded them for the very first time, later netting a Nobel Prize for three scientists who made key contributions to the development of this “black hole telescope.” The newly detected black holes were each around 30 to 35 times the mass of the sun, and they were spinning very slowly, said Maximiliano Isi, an assistant professor of astronomy at Columbia University and an astrophysicist at the Flatiron Institute’s Center for Computational Astrophysics in New York City. Isi led a new study for the LIGO-Virgo-KAGRA Collaboration on the GW250114 data. “The black holes were about 1 billion light years away, and they were orbiting around each other in almost a perfect circle,” Isi said. “The resulting black hole was around 63 times the mass of the sun, and it was spinning at 100 revolutions per second.” These characteristics make the merger an almost exact replica of that first, groundbreaking detection from 10 years ago, according to Isi. “But now, because the instruments have improved so much since then, we can see these two black holes with much greater clarity, as they approached each other and merged into a single one,” he added. Isi said the observation gives scientists a totally new view into “the dynamics of space and time.”
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Mitman is one of the authors of the study that analyzed this signal, titled “Black Hole Spectroscopy and Tests of General Relativity with GW250114,” which was published in Physical Review Letters on January 29. The research was carried out by the LIGO Scientific Collaboration along with the Virgo Collaboration in Italy and the KAGRA Collaboration in Japan. Scientists from Cornell have been deeply involved in the LIGO-VIRGO-KAGRA effort since it began in the early 1990s. When two black holes merge, the newly formed object vibrates, much like a struck bell. These vibrations produce distinct tones defined by two measurements, Mitman explained: an oscillation frequency and a damping time. Measuring a single tone allows scientists to calculate the mass and spin of the final black hole. Detecting two or more tones makes it possible to perform multiple, independent checks of those same properties, as predicted by general relativity. “What’s fantastic is the event is pretty much identical to the first one we observed 10 years ago, GW150914. The reason it’s so much clearer is purely because our detectors have become much more accurate in the past 10 years,” said Cornell physicist Keefe Mitman.
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LIGO, which also has two smaller sister instruments, Virgo in Italy and KAGRA in Japan, is managed by a global scientific community of about 1,600 researchers. It works by detecting tiny stretches in space caused by the gravitational waves which amount to “a change in distance that is 1,000 times smaller than the radius of the nucleus of an atom,” as Isi puts it. Scientists have used it to observe over 300 black hole mergers so far. Earlier, the instrument detected the most massive black hole collision to date between two black holes approximately 100 and 140 times the mass of the sun. Since it debuted, some of LIGO’s key components, including its lasers and mirrors, have been upgraded to increase accuracy and reduce background noise. This improved performance made its new observation over three times more precise than the inaugural one a decade ago. This unprecedented clarity allowed astronomers to use GW250114 to confirm predictions about black holes made decades ago by prominent physicists. The first prediction, devised by New Zealand mathematician Roy Kerr in 1963, builds upon Einstein’s theory of general relativity, and states that black holes should be paradoxically simple objects, described by a single equation. “Yes, black holes are very mysterious, complex and have important implications to the evolution of the universe,” Isi said, “but mathematically we think they should be fully described by just two numbers. Everything there is to know about them should come from how big the black hole is, or what its mass is, and how fast it’s rotating.”
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The gravitational wave called GW250114 was produced when two black holes crashed into one another, sending ripples through space-time. That signal reached the US-based Laser Interferometer Gravitational-Wave Observatories (LIGO) on 14 Jan, 2025. Gravitational waves are named using the date they are detected, and the LIGO-VIRGO-KAGRA team announced this event publicly in September 2025. According to the researchers’ analysis, the signal matches the predictions of general relativity. At the same time, scientists believe future black hole mergers may behave differently, creating opportunities to explore the basic laws that govern the universe. In the case of GW250114, the signal was strong enough for researchers to measure two distinct tones and place limits on a third. All of those measurements were consistent with Einstein’s theory. “Then we would have had a lot of work to do as physicists to try to explain what’s going on and what the true theory of gravity would be in our universe,” Mitman said. He and his collaborators think it is possible that future gravitational wave detections will not fully follow general relativity, potentially shedding light on unanswered questions.
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To test the theory, the researchers used a unique feature of black hole collisions: a “ringing” or vibration, like a bell that’s been struck, that the final black hole produces. “If you have a bell and you strike it with a hammer, it will ring,” Isi noted. “The pitch and duration of the sound, the characteristics of the sound, tell you something about what the bell is made of. With black holes something similar happens, they ring in gravitational waves.” This ringing includes information about the structure of the black hole and the space around it, Isi added. Although the phenomenon was faintly observed before, GW250114 returned a signal with “two modes … a fundamental mode and an overtone” with much more clarity. “We identified two components of this ringing, and that allowed us to test that this black hole really is consistent with being described by just two numbers, mass and rotation,” he said. “And this is fundamental to our understanding of how space and time works, that these black holes should be featureless, in some way. It’s the first time we are able to see this so compellingly.” Many physicists already suspect that general relativity cannot be the final description of gravity. As Mitman noted, the theory does not explain gravitational phenomena linked to dark energy and dark matter, and it breaks down when scientists attempt to reconcile it with the laws that describe the quantum realm.
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The second prediction confirmed by GW250114 is one made in 1971 by British physicist Stephen Hawking, which states that when two black holes merge, the resulting surface area must be equal to or greater than that of the original black holes. “It’s a profound, but very simple theorem that says the total surface area of a black hole can never decrease, it can only get bigger or stay the same,” Isi said. Although previous LIGO observations offered tentative confirmations of the theorem, the clarity of this new signal gives researchers unparalleled confidence, Isi said. In this simulation of the GW250114 event, gravitational waves grow in magnitude, peaking as the black holes merge, and then decreasing rapidly as the newly formed remnant black hole settles. “Because we’re able to identify the portion of the signal that comes from the black holes early on, as they are separated from each other, we can infer their areas from that,” he explained. “Then we can look at the very final portion of the signal that comes from the final black hole, and measure its own area.” Just like Kerr’s equation, Hawking’s theorem also uses Einstein’s work as its foundation: “Einstein’s theories are like the operating system for all of this,” Isi explained. Kip Thorne, one of the three recipients of the Nobel Prize for LIGO contributions, said Hawking called him as soon as he learned of the 2015 gravitational wave detection to ask if LIGO would be able to test his theorem. “If Hawking were alive, he would have reveled in seeing the area of the merged black holes increase,” Thorne said of the esteemed physicist. It’s remarkable how this seminal, theoretical work is being confirmed decades later with advanced instruments, Isi said. And confirming Hawking’s equation, he added, could have implications for a very sought-after goal in physics, combining the seemingly incompatible theory of general relativity, which describes gravity, with quantum mechanics, which relates to the subatomic world.
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“LIGO has created an entire new branch of astronomy. It has revolutionized what we think about compact objects, black holes in particular,” he said. “Before LIGO turned on, people weren’t even sure that black holes could merge and crash and form in this way.” There has to be some way to resolve this paradox to make our theory of gravity consistent with our theory of quantum mechanics. Along those lines, we expect there to be some deviation from Einstein’s classical prediction, where you might see signatures of quantum gravity imprinting themselves on these gravitational wave signals. The hope is that we’ll see these deviations one day and that will help guide us along what the true theory of quantum gravity might be. Gravitational waves are very weak, and the titanic task of detecting them is often described as looking for a needle in a haystack, according to Emanuele Berti, a professor of physics and astronomy at Johns Hopkins University who was not involved with the study. He described the LIGO detectors as “hearing aids” that help with this process. “A large group of scientists spent the last ten years improving those hearing aids, and now we can ‘hear’ the signals with much higher clarity,” he said. “We can now test fundamental principles of gravity that we could not test ten years ago.”
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Among these principles, he added, is the idea that black holes are the simplest macroscopic objects in the universe. The level of detail in the “ringing” produced by the GW250114 collision means scientists can say with confidence that the final object is consistent with the black holes predicted by Einstein’s general relativity, which Berti says is “terribly exciting.” Leor Barack, a professor of mathematical physics at the University of Southampton in England who was also not part of the study, noted that among the more than 300 black-hole merger events recorded by LIGO, the latest one stands out as “particularly spectacular,” and calls the new study a long-awaited analysis. Scientists were able to extract two of the “pure tones” of the remnant black hole as it settled into its final form, Barack added. “This included, for the first time, a clear extraction of the first ‘overtone,’ a fainter harmonious sound of the ringing hole, in addition to the primary tone,” he said. “This kind of test is the most precise to date, by a long margin.” New type of supernova ‘looks like nothing anyone has ever seen before,’ astronomer says. The study represents a significant milestone in gravitational wave astronomy. The detection of a second tone in the “ringing” black hole is particularly significant, GW250114 demonstrates the success of LIGO’s ongoing improvements and shows that gravitational wave detections can test fundamental physics in ways never before possible.
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