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Gravitational Waves Reveal Lightest Black Hole Ever Observed (sciencemag.org) 44

sciencehabit shares a report from Science Magazine: Gravitational wave detectors have spotted a cosmic collision in which a giant black hole swallowed up a mystery object seemingly too heavy to be a neutron star, but too light to be a black hole. Weighing in at 2.6 times the mass of the Sun, the object falls into a hypothetical "mass gap," a desert between the heaviest neutron star and the lightest black hole that some theories predict -- suggesting the gap doesn't exist and that those theories need to be amended. The data come from physicists working with the Laser Interferometer Gravitational-Wave Observatory (LIGO), a pair of detectors in Louisiana and Washington state, and Virgo, a similar detector in Italy.

It's the 2.6-solar-mass object that raises eyebrows because it falls squarely in the mass gap, says Vicky Kalogera, an astrophysicist and LIGO team member from Northwestern University. "Now, for the first time, we have seen such an object," she says. By sensing only the gravitational waves from the collision, LIGO and Virgo cannot tell for sure what the object is, she says. But nuclear physics suggests a neutron star heavier than about 2.2 solar masses cannot support its own weight, so the object is "almost certainly" a black hole, Miller says.
The study has been published in The Astrophysical Journal Letters.
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Gravitational Waves Reveal Lightest Black Hole Ever Observed

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  • I just read "the whitest black hole ever", and I was like, woah, that's racist.
  • Comment removed (Score:5, Informative)

    by account_deleted ( 4530225 ) on Thursday June 25, 2020 @03:48AM (#60225566)
    Comment removed based on user account deletion
    • What does adding a neutron to the largest possible neuteon star do other than start a black hole?

      • Current understanding is that black holes can't exist less than 5 solar masses, it takes that much mass to overcome the quark degeneracy pressure to collapse to a singularity.

        The mass gap is that neutron stars can't exist above 2.5 solar masses because the strong nuclear effect collapses at that point. Quantum stars have been theorized to fill the gap, essentially above 2.5 solar masses the star collapses further to quantum particles, this would hold with quark degeneracy pressure until the star had enough

    • Could it be a supercritical state that spontaneously collapses?

      • That's an interesting point. It may be that stars can't exist in stable state in this mass gap, but can exist in a metastable state in the same way that liquid water at atmospheric pressure can exist at temperatures well over 100C. Just don't depend on it staying that way for long.

  • (and I do mean heavy!) Surely there are other possibilities than just black holes and neutron stars. Presumably something in the signal eliminates stars and the like.

    • by quenda ( 644621 ) on Thursday June 25, 2020 @04:26AM (#60225634)

      Presumably something in the signal eliminates stars and the like.

      Yes. To merge like that, the objects must be very small and dense. Black holes and neutron stars are the only known objects that fit. A black hole cannot collide with a star in the same way that an aircraft cannot collide with a cloud :-)

        The very well tested theories do not allow anything else so dense, that we know of. Less strongly, theory says neutron stars of that mass are unstable, so it almost certainly is a black hole. There is no theoretical reason why black holes of that size cannot exist. We just don't know how they form, and have never seen one before.

      • by ebyrob ( 165903 )

        When was the first well accepted observation by a LIGO?

        How can we be sure something even happened let alone that it was within this specified mass, or that the acceleration magnitude and direction was as expected to actually even separate mass from acceleration?

        Seems just a bit thin to be refuting models with this data yet...

      • There is no theoretical reason why black holes of that size cannot exist. We just don't know how they form, and have never seen one before.

        That's not entirely correct: LIGO has already observed the merger of two neutron stars to form a black hole in this mass range. So that's technically both an observation of one and how it was formed.

        Of course, from what we know this has a low chance of happening and it might, therefore, be statistically unlikely to expect to see a subsequent merger involving one of these objects but we do at least have one confirmed formation mechanism.

        From what I understand though there is no known reason why a supe

    • by Sique ( 173459 ) on Thursday June 25, 2020 @05:43AM (#60225726) Homepage
      The problem with the "very heavy rock" theory is the fact, that it is too massive. When some mass is larger than 1.4 solar masses, and it doesn't have any internal energy resources to build up electromagnetic pressure like a normal star does, it collapses under its own weight. For some time, it glows as a White Dwarf, thus radiating the potential energy of the outer rocky shells, when they fall into the star's center, as light. We can rule out that possibility, otherwise we would detect the spectrum of the White Dwarf there. Thus, this object is not glowing anymore. As there is nothing stopping it from contracting more and more, it becomes a neutron star. There, the strong force keeps it from contracting even more under its own weight, as neutrons as fermions also have to adhere to Pauli's principle. But the strong force only carries until about 3.0 solar masses, and after that, it shrinks to a Black hole.
      • When some mass is larger than 1.4 solar masses

        It's more specific than that: this applies to stars, not to all masses in general since it is the density that actually matters. Theoretically, you can create black holes with subatomic particle collisions which would have masses a tad under 1.4 times the mass of the sun. However, the energies required (in the absence of new physics) are extreme: about 15 orders of magnitude higher than the Large Hadron Collider.

        • by Sique ( 173459 )
          Lets put it this way: Masses smaller than 1.4 solar masses need energy input to contract into a neutron star or a black hole.

          For masses larger than 1.4 solar masses you just have to wait until the type 1A supernova happens.

  • It sounds nice if you claim that the mass 'falls squarely into the mass gap' but if the calculated mass is 20% higher then you have already bridged the mass gap.

    It's a strong statement to claim that the mass was estimated with a smaller error margin than 20%. I'd challenge that first.

    • Re: (Score:3, Interesting)

      by bbruun ( 1697266 )
      To answer your statement about OP's mass gap "claim":

      For decades, astronomers have been puzzled by a gap that lies between neutron stars and black holes: the heaviest known neutron star is no more than 2.5 times the mass of our sun, or 2.5 solar masses, and the lightest known black hole is about 5 solar masses. The question remained: does anything lie in this so-called mass gap?

      Src: https://www.sciencedaily.com/r... [sciencedaily.com].

  • by doug141 ( 863552 ) on Thursday June 25, 2020 @06:31AM (#60225802)

    TFA:
    LIGO and Virgo have shown that it’s possible to form a low-mass black hole in a different way [from supernovas]. In August 2017, they spotted the merger of two neutron stars, which produced, presumably, a black hole of 2.7 solar masses.

  • image_of_black_hole [meshpage.org]

    It's sligghtly dark..

  • And set photon torpedoes to "rinse". There's no telling what will come out of that hole, but it must be wiped out!
    • And set photon torpedoes to "rinse".

      But only if you've already been to here [krapschass.lu]. Or else, you'll have to rinse again...

  • I can't really begin to understand the details of this, but is it possible that we may have looked at the area this occurred in with a regular telescope? I mean, we can't see the black hole (except by lensing), but we might be able to see a star, if that's what it collided with - and now presumably there is no such star, which we should also be able to see. Likewise, if it's a black hole, then we can't see that either, so whilst not as dramatic, would add some weight (see what I did there?) to the argument

    • They tried. Black holes emit no light, so mergers cannot be seen.

      "When the LIGO and Virgo scientists spotted this merger, they immediately sent out an alert to the astronomical community. Dozens of ground- and space-based telescopes followed up in search of light waves generated in the event, but none picked up any signals."

      "According to the LIGO and Virgo scientists, the August 2019 event was not seen by light-based telescopes for a few possible reasons. First, this event was six times farther away tha
  • Not mentioned in TFA, but couldn't Hawking Radiation have weaned its mass from above the mass gap?
    Though, I guess it would be shining very brightly if that were the case.
    • Re:Hawking Radiation (Score:5, Interesting)

      by TrekkieGod ( 627867 ) on Thursday June 25, 2020 @08:40AM (#60226154) Homepage Journal

      Not mentioned in TFA, but couldn't Hawking Radiation have weaned its mass from above the mass gap?

      Hawking radiation for an object of 2.6 solar masses is so tiny, it actually can't lose mass at the current stage of the universe. At that mass, the black hole temperature is around 2.4x10^-8 K, which is far below the temperature of the CMB at 2.7 K. Basically, the black hole is gaining mass from the CMB, and will continue to do so until the universe expansion cools down the CMB temperature by many orders of magnitude.

    • Universe too Young (Score:4, Informative)

      by Roger W Moore ( 538166 ) on Thursday June 25, 2020 @08:59AM (#60226232) Journal
      Not unless the universe is a LOT older than it appears. It takes on the order of 10^64 years for a BH to evaporate (supermassive ones like Sag A* take about 10^100 years). As far as we know the universe is a bit over 10^10 years old (13.8 billion years since the Big Bang).
  • Could it be a black hole that was so small it began evaporating?

    And for the trolls and morons, "evaporation" is by Hawking radiation.

    • The universe isn't old enough for any stellar remnant black hole to lose anything noticeable by evaporation, a 2 solar mass black hole will take about 8 times 10 to the 67th power years to evaporate.

  • I would think that there must be exceptions to any mass gap because surely the mass gap applies to the formation of the bodies... not their future evolution in the presence of added mass from companions or the like. So if a neutron star forms initially and mass is slowly trickled into it, can it not become a black hole through the back door rather than in its initial supernova? And be of whatever mass ends up exhausting the additional supply.

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