Astrophysics news, articles and features | Âéśš´ŤĂ˝ /topic/astrophysics/ Science news and science articles from Âéśš´ŤĂ˝ Thu, 28 May 2026 08:47:35 +0000 en-US hourly 1 https://wordpress.org/?v=7.0.1 242057827 The hidden pockets of the universe where the future can cause the past /article/2526781-the-hidden-pockets-of-the-universe-where-the-future-can-cause-the-past/?utm_campaign=RSS|NSNS&utm_content=astrophysics&utm_medium=RSS&utm_source=NSNS Mon, 18 May 2026 08:00:40 +0000 /?post_type=article&p=2526781 2526781 Black hole stars really do exist in the early universe /article/2508512-black-hole-stars-really-do-exist-in-the-early-universe/?utm_campaign=RSS|NSNS&utm_content=astrophysics&utm_medium=RSS&utm_source=NSNS Mon, 22 Dec 2025 10:00:37 +0000 /?post_type=article&p=2508512 2508512 A distant galaxy is being strangled by the cosmic web /article/2503265-a-distant-galaxy-is-being-strangled-by-the-cosmic-web/?utm_campaign=RSS|NSNS&utm_content=astrophysics&utm_medium=RSS&utm_source=NSNS Fri, 07 Nov 2025 16:00:45 +0000 /?post_type=article&p=2503265 2503265 Is the expansion of the universe slowing down? /article/2503263-is-the-expansion-of-the-universe-slowing-down/?utm_campaign=RSS|NSNS&utm_content=astrophysics&utm_medium=RSS&utm_source=NSNS Thu, 06 Nov 2025 02:38:21 +0000 /?post_type=article&p=2503263
The Tycho supernova remnant
NASA/CXC/RIKEN & GSFC/T. Sato et al; DSS

It is widely thought that our universe is expanding at an ever-accelerating rate. But could we have that wrong? That is what a group of scientists from South Korea claims, but other scientists have major concerns about the work.

Our universe has been expanding since the big bang 13.8 billion years ago. Several strands of evidence, including observations of distant dying stars called type Ia supernovae, have suggested that this expansion is accelerating. One of the main explanations for the driver of this acceleration is a mysterious force called dark energy, the discovery of which won the 2011 Nobel prize in physics.

at Yonsei University in South Korea and his colleagues now say this might be wrong. Type Ia supernovae are caused when the remnant core of a star like our sun, known as a white dwarf, explodes in a binary system. Astronomers use these “standard candles” as trustworthy measurements of distance across the cosmos because they are thought to be uniformally bright.

But Lee and his team say the brightness varies strongly with the age of the stars, based on their analysis of 300 host galaxies. They say that distant supernovae may appear to be fainter than expected and this is usually put down to the accelerating expansion of the universe, but, once this “age bias” is taken into account, the accelerating expansion disappears.

Instead, Lee says their findings suggest the expansion of the universe began decelerating 1.5 billion years ago, and could even reverse in the future, a scenario called the “big crunch” in which the universe could end in a reverse big bang. Previously, he says, “a big crunch was out of the question. But now it is a possibility.”

at the Space Telescope Science Institute in Maryland, one of the recipients of the 2011 Nobel prize in physics, disagrees with that claim, pointing to earlier work by the group in 2020 that had been refuted. “The same group’s new work repeats the argument with little change,” he says, noting that making measurements of stellar ages for type Ia supernovae at large distances is very difficult. He says Lee’s team used a mean stellar age derived from the host galaxy. “The theory behind this is weak because of a lack of certainty about how the [star] forms,” says Riess.

There are known issues with how age affects the brightness of type Ia supernovae across the universe, says at the University of Southampton, UK, but these are already accounted for in measurements of dark energy. “I’m very sceptical this will lead to a decelerating universe,” he says.

Upcoming observations with the Vera C. Rubin Observatory in Chile are expected to greatly expand the number of known type Ia supernovae in the universe, from the thousands catalogued today to tens of thousands. That will allow us to “map the expansion history” of the universe much further back in time, says Sullivan, potentially ruling out the claims from Lee’s team.

The exact nature of dark energy, however, remains mysterious. Earlier this year, results from the Dark Energy Spectroscopic Instrument survey indicated that dark energy might not be a constant force, but could vary over time. While that wouldn’t mean the universe was decelerating right now, it might suggest that the expansion rate has changed over the history of the universe.

“The needle is pointing a lot more to dark energy being some kind of dynamical thing, not a cosmological constant,” says at Queen Mary University of London. “Exactly what that is, I think, is a really interesting question.”

Journal reference

Monthly Notices of the Royal Astronomical Society

Jodrell Bank with Lovell telescope

Mysteries of the universe: Cheshire, England

Spend a weekend with some of the brightest minds in science, as you explore the mysteries of the universe in an exciting programme that includes an excursion to see the iconic Lovell Telescope.

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The end of US support for the CMB-S4 telescope is devastating /article/2501480-the-end-of-us-support-for-the-cmb-s4-telescope-is-devastating/?utm_campaign=RSS|NSNS&utm_content=astrophysics&utm_medium=RSS&utm_source=NSNS Wed, 29 Oct 2025 18:00:00 +0000 http://mg26835670.100 2501480 Quantum-inspired algorithm could help reveal hidden cosmic objects /article/2501892-quantum-inspired-algorithm-could-help-reveal-hidden-cosmic-objects/?utm_campaign=RSS|NSNS&utm_content=astrophysics&utm_medium=RSS&utm_source=NSNS Tue, 28 Oct 2025 20:46:45 +0000 /?post_type=article&p=2501892 2501892 There is an odd streak in the universe – and we still don’t know why /article/2498128-there-is-an-odd-streak-in-the-universe-and-we-still-dont-know-why/?utm_campaign=RSS|NSNS&utm_content=astrophysics&utm_medium=RSS&utm_source=NSNS Fri, 03 Oct 2025 15:00:27 +0000 /?post_type=article&p=2498128 2498128 How faster-than-light explosions could reveal the universe’s secrets /article/2495828-how-faster-than-light-explosions-could-reveal-the-universes-secrets/?utm_campaign=RSS|NSNS&utm_content=astrophysics&utm_medium=RSS&utm_source=NSNS Wed, 24 Sep 2025 15:00:24 +0000 /?post_type=article&p=2495828 2495828 Gravitational waves finally prove Stephen Hawking’s black hole theorem /article/2495377-gravitational-waves-finally-prove-stephen-hawkings-black-hole-theorem/?utm_campaign=RSS|NSNS&utm_content=astrophysics&utm_medium=RSS&utm_source=NSNS Wed, 10 Sep 2025 15:00:58 +0000 /?post_type=article&p=2495377 When two black holes collide and merge, they release gravitational waves. These waves can be detected by sensitive instruments on Earth, allowing scientists to determine the mass and spin of the black holes. The clearest black hole merger signal yet, named GW250114 and recorded by LIGO in January 2025, offers new insights into these mysterious objects.
Illustration of two black holes merging and sending gravitational waves across the cosmos
Maggie Chiang for Simons Foundation
Stephen Hawking’s 50-year-old theorem on how black holes merge together has been successfully tested thanks to huge advances in gravitational wave astronomy, which helped astronomers catch the waves caused by an unusually powerful collision as they passed Earth at the speed of light. Hawking proposed his black hole area theorem in 1971, which states that when two black holes merge, the resulting black hole’s event horizon – the boundary beyond which not even light can escape the clutches of a black hole – cannot have an area smaller than the sum of the two original black holes. The theorem echoes the second law of thermodynamics, which states that the entropy, or disorder within an object, never decreases. Black hole mergers warp the fabric of the universe, producing tiny fluctuations in space-time known as gravitational waves, which cross the universe at the speed of light. Five gravitational wave observatories on Earth hunt for waves . They include the two US-based detectors of the Laser Interferometer Gravitational-Wave Observatory (LIGO) plus the Virgo detector in Italy, KAGRA in Japan and GEO600 in Germany, operated by an international collaboration known as LIGO-Virgo-KAGRA (LVK). The recent collision, named GW250114, was almost identical to the one that created the first gravitational waves ever observed in 2015. Both involved black holes with masses between 30 and 40 times the mass of our sun and took place about 1.3 billion light years away. This time, the upgraded LIGO detectors had three times the sensitivity they had in 2015, so they were able to capture waves emanating from the collision in unprecedented detail. This allowed researchers to verify Hawking’s theorem by calculating that the area of the event horizon was indeed larger after the merger. When black holes collide, they produce gravitational waves with overtones like the ringing of a bell, says at the University of Portsmouth, UK, a member of the LVK team. Previously these overtones have dissipated too quickly to be observed with enough clarity to calculate the area of the event horizons before and after the collisions, which was necessary to test Hawking’s theory. A 2021 study on the first detected collision backed up the theory with a confidence level of 95 per cent, but the new research raises that confidence to a compelling 99.999 per cent.
In the 10 years that scientists have been observing gravitational waves, they have recorded some 300 black hole collisions. But none have been captured as strongly and clearly as GW250114, which was twice as loud as any other gravitational wave detected to date. “The ones that are really, really close by – really, really loud in our data – they’re the ones where we can really start probing into the fundamental physics of what’s going on, just because they’re so loud and the uncertainties are so small. So we can start really picking out the nitty gritty details of what’s going on,” says Nuttall. “We’re just waiting for nature to keep giving us those beautiful things.” Only LIGO was operating when the waves from GW250114 reached Earth, not the other detectors monitored by the LVK collaboration. This didn’t affect the test of Hawking’s theory but did mean researchers were unable to pinpoint the origin of the waves in the sky more clearly. Upgrades to LIGO and other planned observatories due to come online in the future will bring even greater sensitivity and allow us to delve deeper into the physics of black holes, says also at the University of Portsmouth and part of the LVK team. “We may not get all of them, but we will get an event like this again,” says Harry. “Maybe with the next set of upgrades, maybe in 2028, we see something like this and maybe then it’s at the sensitivity where we can really poke holes.” The findings pave the way for new research on quantum gravity, through which physicists hope to unite general relativity and quantum physics. Nuttall says the latest results show general relativity and quantum mechanics continue to work well together, but some discrepancy is expected in the future. “At some point we may start to see that things stop playing nicely, and this will be when we get very close-by signals that just appear extremely loud in our data as the sensitivity of the instruments increases,” says Nuttall. The latest data from LVK also enabled scientists to confirm mathematician Roy Kerr’s equations from the 1960s which predicted that black holes can be characterised by just two metrics: their mass and their spin. In essence, two black holes with the same mass and spin are mathematically identical. Thanks to the observations of GW250114, we now know that to be true.
Jodrell Bank with Lovell telescope

Mysteries of the universe: Cheshire, England

Spend a weekend with some of the brightest minds in science, as you explore the mysteries of the universe in an exciting programme that includes an excursion to see the iconic Lovell Telescope.

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Oddly viscous stars could be impersonating black holes /article/2491843-oddly-viscous-stars-could-be-impersonating-black-holes/?utm_campaign=RSS|NSNS&utm_content=astrophysics&utm_medium=RSS&utm_source=NSNS Fri, 08 Aug 2025 21:00:33 +0000 /?post_type=article&p=2491843 2491843