New observations of two black holes merging have confirmed predictions made decades ago by Albert Einstein, Stephen Hawking, and Roy Kerr.
A decade ago, scientists first picked up ripples in the fabric of space-time, known as gravitational waves, produced by the collision of two black holes. Now, aided by improved instrumentation and a stroke of good fortune, a newly observed black hole merger offers the most definitive view so far of how black holes behave — and, in the process, provides long-sought confirmation of key predictions by Albert Einstein and Stephen Hawking.
The latest measurements come from the Laser Interferometer Gravitational-Wave Observatory (LIGO), with analyses led by astrophysicists Maximiliano Isi and Will Farr of the Flatiron Institute’s Center for Computational Astrophysics in New York City. The findings illuminate black hole properties and the underlying structure of space-time, suggesting possible points of contact between quantum physics and Einstein’s general relativity.
“This is the clearest view yet of the nature of black holes,” says Isi, who is also an assistant professor at Columbia University. “We’ve found some of the strongest evidence yet that astrophysical black holes are the black holes predicted from Albert Einstein’s theory of general relativity.”
The findings were recently published in the journal Physical Review Letters by the LIGO-Virgo-KAGRA Collaboration.
Black Holes and Gravitational Waves
For massive stars, black holes mark the final step in their life cycles. Their gravity is so intense that even light cannot escape. When two black holes collide, they warp space itself and generate gravitational waves that travel outward across the cosmos, similar to the way a bell rings after being struck.
Those space-deforming ripples, called gravitational waves, can tell scientists a great deal about the objects that created them. Just as a large iron bell makes different sounds than a smaller aluminum bell, the “sound” a black hole merger makes is specific to the properties of the black holes involved.
Scientists can detect gravitational waves with special instruments at observatories such as LIGO in the United States, Virgo in Italy, and KAGRA in Japan. These instruments carefully measure how long it takes a laser to travel a given path. As gravitational waves stretch and compress space-time, the length of the instrument, and thus the light’s travel time, changes minutely. By measuring those tiny changes with great precision, scientists can use them to determine the black holes’ characteristics.
The newly reported gravitational waves were found to be created by a merger that formed a black hole with the mass of 63 suns and spinning at 100 revolutions per second. The findings come 10 years after LIGO made the first black hole merger detection. Since that landmark discovery, improvements in equipment and techniques have enabled scientists to get a much clearer look at these space-shaking events.
“The new pair of black holes are almost twins to the historic first detection in 2015,” Isi says. “But the instruments are much better, so we’re able to analyze the signal in ways that just weren’t possible 10 years ago.”
With these new signals, Isi and his colleagues got a complete look at the collision from the moment the black holes first careened into each other until the final reverberations as the merged black hole settled into its new state, which happened only milliseconds after first contact.
Previously, the final reverberations were difficult to capture, as by that point, the ringing of the black hole would be very faint. As a result, scientists couldn’t separate the ringing of the collision from that of the final black hole itself.
Unlocking the Ringing of Black Holes
In 2021, Isi led a study showcasing a cutting-edge method that he, Farr, and others developed to isolate certain frequencies — or ‘tones’ — using data from the 2015 black hole merger. This method proved powerful, but the 2015 measurements weren’t clear enough to confirm key predictions about black holes. With the new, more precise measurements, though, Isi and his colleagues were more confident they had successfully isolated the milliseconds-long signal of the final, settled black hole. This enabled more unambiguous tests of the nature of black holes.
“Ten milliseconds sounds really short, but our instruments are so much better now that this is enough time for us to really analyze the ringing of the final black hole,” Isi says. “With this new detection, we have an exquisitely detailed view of the signal both before and after the black hole merger.”
The new observations allowed scientists to test a key conjecture dating back decades that black holes are fundamentally simple objects. In 1963, physicist Roy Kerr used Einstein’s general relativity to mathematically describe black holes with one equation. The equation showed that astrophysical black holes can be described by just two characteristics: spin and mass. With the new, higher-quality data, the scientists were able to measure the frequency and duration of the ringing of the merged black hole more precisely than ever before. This allowed them to see that, indeed, the merged black hole is a simple object, described by just its mass and spin.
The observations were also used to test a foundational idea proposed by Stephen Hawking called Hawking’s area theorem. It states that the size of a black hole’s event horizon — the line past which nothing, not even light, can return — can only ever grow. Testing whether this theorem applies requires exceptional measurements of black holes before and after their merger. Following the first black hole merger detection in 2015, Hawking wondered if the merger signature could be used to confirm his theorem. At the time, no one thought it was possible.
By 2019, a year after Hawking’s death, methods had improved enough that a first tentative confirmation came using techniques developed by Isi, Farr, and colleagues. With four times better resolution, the new data gives scientists much more confidence that Hawking’s theorem is correct.
Black Holes and the Arrow of Time
In confirming Hawking’s theorem, the results also hint at connections to the second law of thermodynamics. This law states that a property that measures a system’s disorder, known as entropy, must increase, or at least remain constant, over time. Understanding the thermodynamics of black holes could lead to advances in other areas of physics, including quantum gravity, which aims to merge general relativity with quantum physics.
“It’s really profound that the size of a black hole’s event horizon behaves like entropy,” Isi says. “It has very deep theoretical implications and means that some aspects of black holes can be used to mathematically probe the true nature of space and time.”
Many suspect that future black hole merger detections will only reveal more about the nature of these objects. In the next decade, detectors are expected to become 10 times more sensitive than today, allowing for more rigorous tests of black hole characteristics.
“Listening to the tones emitted by these black holes is our best hope for learning about the properties of the extreme space-times they produce,” says Farr, who is also a professor at Stony Brook University. “And as we build more and better gravitational wave detectors, the precision will continue to improve.”
“For so long this field has been pure mathematical and theoretical speculation,” Isi says. “But now we’re in a position of actually seeing these amazing processes in action, which highlights how much progress there’s been — and will continue to be — in this field.”
Reference: “GW250114: Testing Hawking’s Area Law and the Kerr Nature of Black Holes” by A. G. Abac, I. Abouelfettouh, F. Acernese, K. Ackley, C. Adamcewicz, S. Adhicary, D. Adhikari, N. Adhikari, R. X. Adhikari, et al. (LIGO Scientific, Virgo, and KAGRA Collaborations), 10 September 2025, Physical Review Letters.
DOI: 10.1103/kw5g-d732
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10 Comments
Repetitious rubbish. In 2009 I discovered the true ‘induced radiant coherent pulsing angular lines of attractive force nature of gravity’ similar to how I read that Nikola Tesla discovered how to make a 3-phase A-C motor work; a clear mental image output of the bio-supercomputer between his ears. Lacking professional credentials, retired early on disability and lacking access to large research grants, it took me until 2012 to devise, perform and upload my first gravity demonstration video, to YouTube. Since, I have uploaded four videos to share my lay findings with the masses, most recently last June (https://odysee.com/@charlesgshaver:d/5Gravity:c), switching to Odysee dot com during the phony Covid-19 pandemic after being censored about that by YouTube. While many have been critical of me and my lay discovery none have disproved it. Learning there was a volcanic eruption on a Japanese island concurrent with the first alleged LIGO detection of a gravity wave signal in 2015, informing them of it with no reply and still being denied my discovery, after reading this article and dwelling upon it for several minutes I believe I may have just determined for myself what the LIGO-Virgo-KAGRA Collaboration are actually sensing; sympathetic vibrations of the earth’s iron core to major geological events in the outer shell; a ‘bell in a bottle’ so to speak. Even Einstein questioned his “space-time,” and Kerr and Hawking can still be right about black hole mass and spin and event horizons, respectively. As for me, now, to paraphrase an old adage, it seems that ‘a milligram of genius is worth a kilogram of higher education.’ Prove me wrong if you can.
Yeah, it seems whenever some science rubs up wrong against the Einstein/Hawking nonsense (hmmm, seems they were they wrong!), they rush out some fluff to re-bolster that nonsense. Same thing with the quark nonsense, where we’ll likely be awaiting that quant-um computer forever. The solution is to go back to JC Maxwell’s theories and start again, but include bio-photons/bio-metrics in the analysis. But the obstructionists don’t seem to really want a TRUE unified theory, for anything.
Covid wasn’t phony, my aunt died from it and we couldn’t even have a traditional funeral for her. And if you really figured whatever you’re talking about out, you wouldn’t be silenced. You would be heard by all the great scientists, you would be posted in science magazines and books, achievement awards and a guest appearance on star talk with Neil Degrassi Tyson. You’re the phony with disinformation and misinformation.
Sorry for your loss, Ryne, probably preexisting conditions and illegal confinement (most of my immediate and extended family died prematurely much earlier) but the fact of the matter is that since early 1900s mainstream medicine has been primarily oriented toward perpetual treatments for minority profits, not prevention and cures for all mankind. I first wrote the FDA (with replies) of my early lay findings of connections between sub-acute food allergies, added MSG, chronic diseases and obesity in October of 2005 (obviously, now, in-vain), thousands more since, including Neil deGrasse Tyson about gravity, with mostly similar results; outdated dogma prevails. For more details, senior lay perspectives and/or some of my sources: https://odysee.com/@charlesgshaver:d?view=about and/or https://www.foodallergy.org/fare-blog/why-we-need-stop-referring-ige-mediated-allergies-true-food-allergies
If these black holes merged within milliseconds wouldn’t that mean matter traveling faster than the speed of light?
One strategy is to ask just exactly what are the mechanisms of the tests? For instance, the product of one of the main manufacturers of particle detectors is 1″ and 2″ square silicon chips. An output is fed to opamps, which is then fed through CMOS switches to provide trigger signals. If the purported size of any sub-atomic ‘particle’ were compared to the amount of purported ‘particles’ in a 2″ square of silicon, one can see the almost mathematically impossible ratio to any probability for accuracy. And then of course, the 2″ square silicon sits against a moving body of air – not uncomparable, I should think, with one’s ear listening to the whole of the ocean. If one’s ear-canal were filled with sea water.
But the computer graphics are pretty. The math filtering finds exactly what researchers were looking to find.
“a stroke of good fortune” here is biased inferencing and low significance. Read the cited paper.
Sounds like a bunch of poppycock to me. I thinks most of the new science is BS – just something to get research grants which has become big business now days. I always wonder how Einstein got things so right so long ago. Tesla too. They must have had help from a higher source?????? Maybe God maybe aliens – the quantum leaps by these guys is amazing.
Sounds like a bunch of poppycock to me. I thinks most of the new science is BS – just something to get research grants which has become big business now days. I always wonder how Einstein got things so right so long ago. Tesla too. They must have had help from a higher source?????? Maybe God maybe aliens – the quantum leaps by these guys are amazing.
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