Black hole jets, which spew near-light-speed particle beams, can trigger nearby white dwarf stars to explode by igniting hydrogen layers on their surfaces. “We don’t know what’s going on, but it’s just a very exciting finding,” said Alec Lessing, an astrophysicist at Stanford University and lead author of a new study describing the phenomenon, in an ESA release. Gizmodo reports:

In the recent work – set to publish in The Astrophysical Journal and is currently hosted on the preprint server arXiv – the team studied 135 novae in the galaxy M87, which hosts a supermassive black hole of the same name at its core. M87 is 6.5 billion times the mass of the Sun and was the first black hole to be directly imaged, in work done in 2019 by the Event Horizon Telescope Collaboration. The team found twice as many novae erupting near M87’s 3,000 light-year-long plasma jet than elsewhere in the galaxy. The Hubble Space Telescope also directly imaged M87’s jet, which you can see below in luminous blue detail. Though it looks fairly calm in the image, the distance deceives you: this is a long tendril of superheated, near-light speed particles, somehow triggering stars to erupt.

Though previous researchers had suggested there was more activity in the jet’s vicinity, new observations with Hubble’s wider-view cameras revealed more of the novae brightening – indicating they were blowing hydrogen up off their surface layers. “There’s something that the jet is doing to the star systems that wander into the surrounding neighborhood. Maybe the jet somehow snowplows hydrogen fuel onto the white dwarfs, causing them to erupt more frequently,” Lessing said in the release. “But it’s not clear that it’s a physical pushing. It could be the effect of the pressure of the light emanating from the jet. When you deliver hydrogen faster, you get eruptions faster.” The new Hubble images of M87 are also the deepest yet taken, thanks to the newer cameras on Hubble. Though the team wrote in the paper that there’s between a 0.1% to 1% chance that their observations can be chalked up to randomness, most signs point to the jet somehow catalyzing the stellar eruptions.

  • db2@lemmy.world
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    3 months ago

    Now you will see the power of this fully operational battle singularity.

          • lolcatnip@reddthat.com
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            3 months ago

            Ever. It’s not entirely known how supermassive black holes formed, but it’s definitely not from stars. They’re millions of times as massive as the sun.

              • lolcatnip@reddthat.com
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                3 months ago

                Be that as it may, you clearly don’t know what you’re taking about and aren’t interested in learning.

                • a2part2@lemmy.zip
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                  3 months ago

                  You are correct in the first part. It’s always good to learn things. Do you have anything to teach?

                  • lolcatnip@reddthat.com
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                    3 months ago

                    Sorry, I was being cranky.

                    Supermassive black holes (SMBs) are much, much bigger than any star. If you look at this Wikipedia article, you’ll see that the theoretical limit for star size is in the neighborhood of 300 times the mass of the sun. SMBs are at least hundreds of thousands of times more massive than the sun, up to billions of time more massive. They are also probably older than any star because they had to exist the form the seeds of galaxies. One of the open questions in astrophysics right now is how SMBs formed as quickly as they did, because there’s a limit on how quickly a black hole can absorb matter. Any faster than that limit, and the matter falling into the black hole is so hot and dense that a lot of it gets blown outward.

                    If you find this stuff at all interesting, I recommend checking out PBS Space Time on YouTube, particularly their black hole episodes.

    • WhatAmLemmy@lemmy.world
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      3 months ago

      What doesn’t make sense is how haven’t these primordial black holes accumulated to form massive objects that dominate the universe? The distribution of dark matter implies that it’s widely dispersed throughout the universe, amongst all other matter, but wouldn’t these primordial black holes have started to attract matter and grown in mass from 1 second after the Big Bang? Wouldn’t the vast majority of these proton sized black holes no longer be proton sized? Wouldn’t they have grown until they absorbed most visible matter in their vicinity? If this were true wouldn’t it mean most of the dark voids between galaxies and stars are actually gravitationally dominated by black holes of varying sizes? How could our observations to date have missed that? Wouldn’t pointing the JWST at any void show signs of infrared gravitational lensing? Oh god I’ve gone cross-eyed…

      Edit:

      “Even if you take into account clustering, the time scales for the merger are so long that they would only merge into really massive black holes over the entire age of the universe,” he continued.

      If this were true, how have all the sub-atomic particles accumulated to form visible matter and galaxies? Do these black holes somehow have less mass than other particles? If so, how could they possibly make up most of the gravity in the universe — more gravity than all the visible matter — yet their gravity is so weak that they don’t accumulate into larger clusters?

      • Fermion@feddit.nl
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        3 months ago

        Black holes don’t swallow everything around them for the same reason that the sun hasn’t swallowed all the planets. Outside of the event horizon, gravity still works normally and the fact that it’s a singularity doesn’t really matter. Gravitational capture usually involves multiple objects, because the trajectory has to get nudged for a collision to happen. A gaseous body collects mass at a faster rate than a black hole with the same mass.

        • db2@lemmy.world
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          3 months ago

          I’m pretty sure they can “get full” and basically explode also.

            • teft@lemmy.world
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              3 months ago

              Not true. The upper limit is about 50 billion solar masses.

              From wikipedia:

              Supermassive black holes in any quasar or Active galactic nucleus appear to have a theoretical upper limit of physically around 50 billion solar masses as any mass above this slows growth to a crawl (the slowdown tends to start around 10 billion solar masses) and causes the unstable accretion disk surrounding the black hole to coalesce into stars that orbit it.

              • peopleproblems@lemmy.world
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                3 months ago

                Ok a bit more I found.

                The 5×10^10 number you referenced is the SMBH maximum mass for typically observed black holes. However, near the maximum prograde spin, given the age of the universe, a black hole would not have been able to accumulate more than 2.7×10^11 solar masses.

                So, yes, a practical limit exists. But to point to OPs comment, no they will not explode.

              • peopleproblems@lemmy.world
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                3 months ago

                I didn’t know that, but it makes sense that AGN would have a limit. Lemme look this up, we’re pretty close to my limit of astrophysics

              • Wilzax@lemmy.world
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                3 months ago

                There’s a limit to how big they can grow through accretion, yes, but no limit to their mass through mergers.

        • WhatAmLemmy@lemmy.world
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          3 months ago

          Black holes don’t swallow everything around them for the same reason that the sun hasn’t swallowed all the planets.

          I wasn’t implying this. I was referring to how they would gradually increase in mass as they absorb particles that came close enough — the same way that all other matter accumulates.

          Gravitational capture usually involves multiple objects, because the trajectory has to get nudged for a collision to happen.

          What about the countless proton sized blackholes and matter dispersed between them? Wouldn’t they all interact with each other? How come the visible matter accumulated but the black holes did not? Are they so small that they’re all around us but too small to interact with non-primordial black holes?

          A gaseous body collects mass at a faster rate than a black hole with the same mass

          Because the gas/mass is distributed over a larger area? As in, gas has a larger gravitational “dragnet”, relative to its mass?

      • Cocodapuf@lemmy.world
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        3 months ago

        My understanding is that black holes naturally evaporate, releasing energy and sometimes matter out through their polar jets. I believe this is called hawking radiation. Now proton sized black holes can exist (I believe we’ve created them in the LHC), but at that size, the hawking radiation makes the black hole evaporate extremely quickly, like within nano seconds.

        In other words, tiny black holes are very short lived, they rarely have time to absorb more material and grow.

        Edit: well it seems that I was definitely wrong about hawking radiation having anything to do with the polar jets. But I just double checked and it looks like everything else I said is pretty accurate. I’m not sure why the 1 minor inaccuracy was worth downvotes, but whatever.

        • teft@lemmy.world
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          This is an incomplete understanding of modern physics. Hawking radiation isn’t jets. Hawking radiation is when subatomic particles pop into existence and one is below the event horizon and can’t escape or anhillate and the other is above the event horizon and flies away which causes a loss of mass in the black hole due to conservation of energy.

          We aren’t currently sure if micro black holes evaporate or can reach equilibrium at planck scales. Also we haven’t made any black holes at the LHC. You would need something like 10 billion times more energy for the LHC to form black holes.

          • lolcatnip@reddthat.com
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            3 months ago

            physics. Hawking radiation isn’t jets. Hawking radiation is when subatomic particles pop into existence and one is below the event horizon

            I don’t believe that’s correct. At least, the last time I looked into it, the sources I looked at specifically said that version is oversimplified to the point of just being wrong.

            • teft@lemmy.world
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              3 months ago

              What source are you referring to? I’d like to read it as that would contradict everything I’ve ever read on hawking radiation.

              • lolcatnip@reddthat.com
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                3 months ago

                The Wikipedia article kind of alludes to it, but this article by John Baez pretty much comes out and says the virtual particle explanation makes no sense.

              • Wilzax@lemmy.world
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                3 months ago

                The virtual particle explanation is wrong because it implies that virtual particles have a negative mass density on one side and a positive mass density on the other, and that by some unexplained mechanism the negative half of that mass density falls into the black hole more commonly than the positive mass density. This is the opposite of what you would expect, as negative mass would have negative acceleration, and would fall AWAY from the gravitational pull of the black hole, not towards it. This is simply not how virtual particles work. This explanation is mistakenly treating virtual particles as classical objects, rather than a phenomenon that is predicted by quantum field theory.

                The real explanation is above my paygrade to describe, but it is a phenomenon related to the Casimir effect, where the space between the metal plates is analogous to space time existing after the creation of the event horizon.

        • lolcatnip@reddthat.com
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          I don’t know how true it is, but I read in another thread recently that Planck mass is about the mass of an eyelash and also the minimum mass of a black hole. Below that mass the location of a particle isn’t localized enough for it to be a black hole. Also IIRC the Schwartzchild radius of such a black hole is something like twice Planck length.

        • peopleproblems@lemmy.world
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          It’s a bit more complicated than that - theoretically Hawking radiation would cause a black hole with no surrounding matter to evaporate over an extremely long period of time (we’re talking 10^10 to 10^100 years).

          Additionally, micro black holes have been proven mathematically in the 14MeV range of LHC, but as far as experimental data goes, we have not observed the creation of a micro black hole. The main problem is that they would instantly annihilate (as in exactly 0 seconds) and would be indistinguishable from events already creating gamma rays.