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Space Earth Sun Microsystems News Science

Monster Black Holes May Lurk All Around Us (yahoo.com) 184

Taco Cowboy quotes a report from Yahoo News: Astronomers have stumbled upon a supermassive black hole in an unexpected corner of the Universe, implying these galactic monsters are much more common than once thought, a study said Wednesday. The giant, with an estimated mass 17 billion times that of our Sun, was discovered in a relative desert, astronomers from the University of California, Berkeley, wrote in the journal Nature. "While finding a gigantic black hole in a massive galaxy in a crowded area of the Universe is to be expected -- like running across a skyscraper in Manhattan -- it seemed less likely they could be found in the Universe's small towns," said a university statement. Big, star-rich galaxies where supermassive black holes had previously been found, are very rare. Smaller ones like the NGC 1600 galaxy housing the newly-discovered whopper, are much more common, but were not previously thought to be appropriate host. "So the question now is: 'Is this the tip of an iceberg?'" said study co-author Chung-Pei Ma. "Maybe there are a lot more monster black holes out there that don't live in a skyscraper in Manhattan, but in a tall building somewhere in the Midwestern plains." The largest supermassive black hole spotted to date tipped the scales at about 21 billion solar masses, said the study authors.
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Monster Black Holes May Lurk All Around Us

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  • by Anonymous Coward

    Was found in an empty space... duh!

  • by DNS-and-BIND ( 461968 ) on Thursday April 07, 2016 @01:09AM (#51858367) Homepage

    it seemed less likely they could be found in the Universe's small towns," said a university statement

    Well that's great and all, but it misses the most important point of this entire story - what kind of shirt was the spokesman wearing when he released the statement? We already know, from empirical experience, that this fashion statement overshadows anything that might have been said or any legitimate human achievement that may have occurred. Up to and including announcing that HUMANITY LANDED A SPACE PROBE ON A GODDAMNED COMET.

    • Re: (Score:2, Flamebait)

      by dave420 ( 699308 )

      People can concentrate on more than one thing at once. You are possibly an exception, which would explain your apparent confusion. Yes, the reaction from some was over the top, but that does nothing to change the fact that someone made a stupid mistake and tarnished the image of their organisation by not being as professional as decorum would expect. And none of this has anything to do with a specific piece of research.

      I get it - you are clearly rather old (or your mentality is, or both), rather grumpy,

  • by wevets ( 939468 ) on Thursday April 07, 2016 @01:29AM (#51858433)
    Maybe the black hole they found used to be in the center of a super massive galaxy, but had already swallowed up most of the galaxy so there's not much left, leaving the impression that its a super massive black hole in the center of a not-so-massive galaxy?
    • by Anonymous Coward on Thursday April 07, 2016 @04:08AM (#51858777)

      When will people stop thinking of black holes as giant vacuum cleaner? They're not. What they are is gigantic masses concentrated in a relatively small space creating big gravity. Other objects massive enough (i.e. stars) spin around them, exactly like planets spin around the sun but don't fall into it.

      • Exactly. Getting 'sucked into' a sun is just as bad for your health as falling into a black hole, but we don't get all freaked out about those. Well, unless we were in a ship that was getting uncomfortably close to a star, in which case we'd probably be becoming worried.

        Black holes do sound pretty cool though, so you can imagine why people might make up stories about them.

      • Re: (Score:3, Informative)

        by Anonymous Coward

        When will people stop thinking of black holes as giant vacuum cleaner? They're not. What they are is gigantic masses concentrated in a relatively small space creating big gravity. Other objects massive enough (i.e. stars) spin around them, exactly like planets spin around the sun but don't fall into it.

        As the center of gravity gains mass, formerly stable orbits become unstable and the orbiting bodies fall into the gravity well. This can result in chain reaction which seemingly acts like a giant vacuum cleaner.

        Other objects massive enough (i.e. stars) spin around them, exactly like planets spin around the sun but don't fall into it.

        Orbits are not a function of mass, anything from an electron to a small black hole can orbit around a supermassive black hole and have the exact same orbit.

        exactly like planets spin around the sun but don't fall into it

        Except the proto-planets that did get sucked up in the Sun while our solar system was being formed.

        • by Maritz ( 1829006 )
          You can gain a whole lot of mass but you're up against the inverse square law. That gravitational 'force' (yes it's really just a geometrical distortion of spacetime) falls away rapidly with distance. The distance is what keeps those remote objects safe.
        • by AthanasiusKircher ( 1333179 ) on Thursday April 07, 2016 @11:06AM (#51860549)

          As the center of gravity gains mass, formerly stable orbits become unstable and the orbiting bodies fall into the gravity well. This can result in chain reaction which seemingly acts like a giant vacuum cleaner.

          One could argue the same thing about a star or even a planet. If enough stuff falls into any astronomical body, its mass could increase and orbits could destabilize.

          Black holes are no different in this regard, hence the reason why it's weird to think of them as special kinds of "vacuum cleaners" that are different from other celestial bodies.

          Except the proto-planets that did get sucked up in the Sun while our solar system was being formed.

          Terms like "sucked up" are the problem. Suction is a specific physical thing created by a vacuum. In that case, the material that is "sucked up" is actually pushed into something else by the fluid pressure difference. It really doesn't make sense to apply this to proto-planets, since they were not pushed into the Sun by some external pressure.

          Rather, they did not have sufficient orbital velocity to avoid falling into the gravity well. Using terminology like "vacuum cleaner" or "suction" is a really bad metaphor because it implies all sorts of things that aren't part of the physical scenario in question.

      • Much like how Jupiter doesn't suck in asteroids? [duckduckgo.com]
    • by Bengie ( 1121981 )
      Ignoring that BHs mostly blow what they "suck in" away with their jets, anything not really close to the BH will be pushed away. The reason most super massive blackholes are almost an exact small percentage, not a random small percentage, of their host galaxy is because they can only pull in so much mass.
    • by Maritz ( 1829006 )
      It wouldn't do that. A black hole is not a magical suck-everything-up machine. It's just a massive object. If your orbit around it is high, you basically won't ever be sucked in.
  • Maybe this is what they have been spending years trying to invent the invisible and undetectable dark matter for?

    • by Sique ( 173459 ) on Thursday April 07, 2016 @02:48AM (#51858603) Homepage
      That's quite not the case. The Dark Matter affects how galaxies rotate.The movement of the outer parts of a large galaxy are in a way as if the galaxy was much heavier than we would expect just from the radiation coming from that galaxy. So we already know that galaxies contain more (gravitationally detectable) matter than we see (elektromagnetically detectable), and that additional matter doesn't emit any light, hence we call it Dark Matter. A supermassive black hole in a small galaxy will not too much affect the rotation of a large galaxy nearby. Thus supermassive black holes in small galaxies won't explain the effects that forced us to postulate the existence of Dark Matter.
      • Comment removed based on user account deletion
        • by Sique ( 173459 ) on Thursday April 07, 2016 @03:39AM (#51858729) Homepage
          They have to be within the galaxies to explain their movement. The outer parts of a galaxy rotate with a speed that is only explainable if the part of the galaxy that is within the orbit of the outer parts is much heavier than just the mass we can detect by the emitted light. And it has to be distributed througout the galaxy as the effect is larger, if we go more far away from the center.

          So neither supermassive black holes in the galaxy's center nor ejected supermassive black holes can explain the effect.

        • by Bengie ( 1121981 )
          DM has been sopped passing through matter also. Unless you know of a way for a blackhole to pass through a large gas cloud and not disturb anything. DM is diffusely distributed, blackholes are concentrated.
      • Unless there are so many super massive black holes that it makes up the difference ...

        You do realize we may not actually know everything about how the universe works right? Hence the point of this article ... there are more black holes than expected ... yet here you are immediately throwing out an idea because you think you know whats going on ... while being shown you don't know whats going on.

        Science doesn't allow for your preference for how the universe works. You don't get to say 'won't explain the ef

        • by Maritz ( 1829006 )
          It doesn't help to explain galactic rotation curves, and it doesn't help with observations like the bullet cluster. Doesn't matter what his preference or yours is.
    • by Maritz ( 1829006 )
      Would be nice but my impression is nope, MACHOs have been considered before, and even with the likes of this it's nowhere near. Also it leaves observations like the Bullet Cluster unexplained.
  • Assuming much more matter has been concentrated, over the lifetime of the universe, into black holes - then is this a usable attempt to explain what we still designate as "black matter" ?

    • No dark matter is the souls of the departed [wikipedia.org], undetectable except by their mass.

    • Some of the evidence for dark matter is that parts of galaxies revolve at a different rate than would be expected if all the matter were of they type we understand. This black hole is much bigger than the black holes in some known galaxies. The rotational speed of those galaxies can't be explained by a super massive black hole in a different galaxy. One of the mysterious effects is the difference in rotational speed as you go out from the center of the galaxy. Again that can't be impacted by something t
      • One of the mysterious effects is the difference in rotational speed as you go out from the center of the galaxy.

        Why can't this be explained by time dilation from the gravity of the black hole? The center is only rotating slower to an outside observer, but could in fact be going the same number of Km/h (to pick a completely off-scale unit).

        • Why can't this be explained by time dilation from the gravity of the black hole? The center is only rotating slower to an outside observer, but could in fact be going the same number of Km/h (to pick a completely off-scale unit).

          It just doesn't. Time dilation is not arbitrary, it has to work in a very specific manner for all the math and the experimental results (and internet) to work.

          The gravitational effect of the accounted for mass in each galaxy doesn't explain their movement.

        • by Maritz ( 1829006 )
          The time dilation effect is highly localised to the black hole.
          • Localized is a bit of a weird way to put it. The effect decreases with distance. But as you go further out, you're also orbiting not just the black hole but the rest of the galaxy in between, meaning more gravitational force in the same direction.

            But how much faster could the outside really be moving compared to the inside if the galaxy still has a distinct spiral shape and hasn't combined into an amorphous disc? If it's been rotating for billions of years, but still has distinct spiral arms, it can't be

            • by Maritz ( 1829006 )
              There are different stars in the spiral arms all the time. They are basically just an area where the stars bunch up. What I mean by the time dilation effect is that just as with increasing your speed up to C, you only really get noticable effects when you're very close to it. You need to be very close to the horizon to get dramatic time dilation effects.
      • One of the mysterious effects is the difference in rotational speed as you go out from the center of the galaxy. Again that can't be impacted by something that's only in the center.

        And yet they treat the galaxy as a point source of gravity at the center. See this post by Sique [slashdot.org] as an example. Plus, if gravity waves are a reality, then gravity must travel at a limited speed. This would mean that things orbit where the gravity was and not where it is now. This would also mean that the stars in the same orbit at the outer edges of the galaxy are affected by the stars ahead in the orbit more than the ones behind in the orbit. Since they are all travelling around together and gravity has a

        • Sorry, stars following would be "red-shifted" and stars ahead would be "blue-shifted". I put those backwards in my first post.
    • Re: (Score:3, Funny)

      Comment removed based on user account deletion
    • No.

      Dark matter isn't just matter we don't see. It's matter that doesn't collide with regular matter, which makes it not conform to galaxies' disk shape.

      • by gtall ( 79522 )

        More to the point, dark matter is matter that doesn't collide with physicists so they get to ascribe to it any perplexing properties they like and then feed it to the rest of us in a bid to act like they do understand how it acts in the universe.

        • by Maritz ( 1829006 )

          Physicists have postulated the existence of cold dark matter because the observations require something to explain them. Large detectors have been built in an attempt to find dark matter. You, on the other hand, have decided that it doesn't exist. What's your explanation, then? Why don't you clear all this up for the rest of us?

          In my experience, when someone characterises the current picture so ungenerously, it's because they're a crank of some kind.

      • Dark matter isn't just matter we don't see. It's matter that doesn't collide with regular matter, which makes it not conform to galaxies' disk shape.

        We don't know for certain that what we are calling "dark matter" is matter at all. Dark Matter is a place holder term used to explain a gap between our observations and our models. We have some guesses as to what it might be and we've ruled out a few possibilities. Calling it some form of weakly interacting matter is among the more reasonable hypothesis but we can't confirm or deny that idea at this time. It also could be some sort of error in our model of how gravity works. Not quite as likely but not

  • Just great. (Score:5, Funny)

    by fahrbot-bot ( 874524 ) on Thursday April 07, 2016 @01:43AM (#51858461)

    Monster Black Holes May Lurk All Around Us

    I thought I only had to watch out for their over-priced HDMI cables.

  • But the human habitation analogies in this piece make me cringe just a bit.

  • We would notice if any supermassive black holes were close enough to affect us

    • close enough to affect us

      Everything in the observable universe is close enough to affect us.

      • by Bengie ( 1121981 )
        Nope. Most of the observable Universe is so far away, it will never interact with us again. It's so far away that it's moving away from us faster than light.
        • Nope. That which cannot interact with us is not observable, and thus beyond the observable universe boundary, by definition.

      • by Maritz ( 1829006 )
        So minutely as to be disregarded, sure.
    • Comment removed based on user account deletion
  • by Shadyman ( 939863 ) on Thursday April 07, 2016 @03:29AM (#51858699) Homepage
    I can verify. There is a giant one in my wallet. I put money in... aaaaaand it's gone.
    • I can verify. There is a giant one in my wallet. I put money in... aaaaaand it's gone.

      If it's thong-shaped and on a stripper, it's not your wallet.

  • Don't get sucked in to a discussion on why black holes don't suck any more than regular objects. That would suck.

  • A relatively young and small galaxy turns out to have a supermassive black hole at its center and people are wondering how it got there? How about this: The galaxy is forming around the black hole, not the other way around.
  • "While finding a gigantic black hole in a massive galaxy in a crowded area of the Universe is to be expected -- like running across a skyscraper in Manhattan"

    The holes have already eaten everything, that's the same reason why there are no penguins on the North-pole, the polar bears ate them all.

  • Nah! (Score:4, Interesting)

    by eyenot ( 102141 ) <eyenot@hotmail.com> on Thursday April 07, 2016 @06:44AM (#51859063) Homepage

    Some nice theories here but I'm sticking with my own pet theory: our observable universe exists entirely inside a black hole, slowly being compressed at the center across time.

    Our measurements that don't take this into account see the universe as "expanding" because our cherry-picked points of reference are actually getting closer together.

    But since this is all happening simultaneously, even our own instruments and myriad points of reference for myriad "constants" are also being compressed, which means it completely goes over our heads and the ruler we think we're holding is much shorter than it actually is.

    Also, being on the inside of an event horizon explains why a universe that's supposed to be lit up with infinite stellar matter is more or less dark. Not the entire actual, "outside" universe is in here, inside this particular black hole, with us.

    The smallest, relatively debris-like space rock outside this black hole might astound us with dimensions the size of the local group, and indeed the local group may have formed long after such a space rock was sucked in past this black hole's event horizon. As the matter from the space rock was siphoned into a stream of particles past the event horizon, and entered into proximity with the particles of other objects that had also been sucked in, their relative closeness exerted some weak influence of gravity and they coalesced into various tiny swirls and clouds.

    Meanwhile, we cannot detect the singularity at the center of the black hole because of the relative proximity of all observable objects near to it. It would just appear to be a "background force" omnipresent over everything, and we would never be able to develop either an instrument to measure the singularity's exerted force because of a lack of possible reference-points.

    This leads to the question "well, since black holes also capture light particles, why isn't all the light of the 'real', 'outside' universe also visible as a sheen all around us at the edges of the visible universe?"

    But we don't have any concept of what happens to light after it crosses an event horizon. For all we know, photons are just energetic enough to whip around the event horizon without ever being perceived again (you'd have to be right on the event horizon, with a line of observation orthogonal to the photon's path -- which is always changing due to the centripetal force pointing inward) and only less energetic forms such as hydrogen actually manage to "fall in" (which would explain the otherwise inexplicable background hydrogen.)

    Sorry if you haven't encountered this theory before, it's entirely my own creation that I came up with just trying to be controversial while lounging around staring at the sky at night. I'm not nearly mathematically creditable enough (only recently passed Differential Equations and completed my minor in mathematics, and majoring in computer engineering, not astrophysics or related fields,) I don't have the time or the fancy, and most importantly of all I wouldn't want to be the one to have to break it to anybody.

    And I'm absolutely sure it would be rejected outright, just because every time I bring it up to anyone they just get stunned and stare off into space. I mainly use it as a psych-out for people who are high or drunk at parties, you know -- to fuck with people.

    • "we would never be able to develop either the instrument..." ... to finish the sentence: "or the observation of a point of reference outside of the local effects of the black hole."

      Also: the main reason this theory isn't acceptable is because, in line with the standards of meritable academe, it can't pass Karl Popper's standard of falsifiability. Unless Thomas Kuhn's theory of experimental paradigm can be modified to disprove that Popper's falsifiability is required for all experimental conclusions -- perha

      • by eyenot ( 102141 )

        And any ways, it's embarrassing. Supposing you offered to include data outside the observable universe, someone trite could ask "oh, yeah? Where'd you get that from?"

        Which all implies that your mother is the size of the observable universe, you know, what with all the talk of light-emitting matter entering the cherry-picked black hole and all, Adam Kadmon, etc.

    • Comment removed based on user account deletion
      • by eyenot ( 102141 )

        I'm glad to hear other people have posited the same theory.

        About the only thing we could hope for (if we're serious -- I'm not too sure that I am in this case) is that enough people support the theory and wait around for all of the thousands of other theories that are based on its exact inverse to eventually fail, leaving no further opposition.

    • Horton, is that you?

    • Some nice theories here but I'm sticking with my own pet theory: our observable universe exists entirely inside a black hole, slowly being compressed at the center across time. ... But since this is all happening simultaneously, even our own instruments and myriad points of reference for myriad "constants" are also being compressed, which means it completely goes over our heads and the ruler we think we're holding is much shorter than it actually is.

      That doesn't fit observations or models of black holes. Fa

    • C [wikipedia.org]/H0 [wikipedia.org] = Rhs [wikipedia.org] Distance to edge of observable Universe is a little bigger because expansion is accelerating and will in the future pass the edge of the Hubble sphere.

    • Reminds me of this post:

      https://science.slashdot.org/comments.pl?sid=578907&cid=23722965 [slashdot.org]

      if you have a galaxy at the center of a collapsing black hole, and are in the galaxy, you cannot tell the difference between that event and a big bang. Moreover, once the SC-radius has formed, you cannot tell whether you are inside the black hole, or outside it as the rest of the universe collapses into it's own black hole. Moreover, because light that goes out from the universe / black hole gets redirected back in

    • by Maritz ( 1829006 )
      You made a hell of a lot of assertions there, with fuck all basis in fact. I'm afraid that is basically meaningless word-salad. I bet the people you 'fuck with' think you're real clever though, and isn't that the main thing?
  • All these hysterical headlines.

    So, I invoke a variation of the Fermi Paradox in relation to black holes. If they were all over the place "lurking" as the article suggests we should see evidence of that through Gravitational Lensing. Random points in space where suddenly we see a 'smear.' Other evidence would be through objects moving in odd was as we see at the center of our own galaxy. I've never read about any of that.

    Last time I checked, we only see lensing where there is a defined galaxy, which then e

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