Become a fan of Slashdot on Facebook

 



Forgot your password?
typodupeerror
×
Space Technology

How Astronomers Will Take the "Image of the Century": a Black Hole 129

An anonymous reader writes with news that scientists may be close to getting the first image of a black hole. "Researchers studying the universe are ramping up to take the image of the century — the first ever image of a supermassive black hole. While the evidence for the existence of black holes is compelling, Scientists will continue to argue the contrary until physical, observational evidence is provided. Now, a dedicated team of astrophysicists armed with a global fleet of powerful telescopes is out to change that. If they succeed, they will snap the first ever picture of the monstrously massive black hole thought to live at the center of our home galaxy, the Milky Way. This ambitious project, called the Event Horizon Telescope (EHT), is incredibly tricky, but recent advances in their research are encouraging the team to push forward, now. The reason EHT needs to be so complex is because black holes, by nature, do not emit light and are, therefore, invisible. In fact, black holes survive by gobbling up light and any other matter — nearby dust, gas, and stars — that fall into their powerful clutches. The EHT team is going to zoom in on a miniscule spot on the sky toward the center of the Milky Way where they believe to be the event horizon of a supermassive black hole weighing in at 4 million times more massive than our sun. We can still see the material, however, right before it falls into eternal darkness. The EHT team is going to try and glimpse this ring of radiation that outlines the event horizon. Experts call this outline the "shadow" of a black hole, and it's this shadow that the EHT team is ultimately after to prove the existence of black holes."
This discussion has been archived. No new comments can be posted.

How Astronomers Will Take the "Image of the Century": a Black Hole

Comments Filter:
  • by Vintermann ( 400722 ) on Friday December 05, 2014 @03:13AM (#48528935) Homepage

    Well, the thing about a Black Hole, its main distinguishing feature, is it's black. And the thing about space, your basic space colour is black. So how are you supposed to see them?

    • Re: (Score:2, Informative)

      by Anonymous Coward

      If you read the summary there is a clue.

    • Re: (Score:2, Informative)

      by Anonymous Coward

      They thought they detected it, but in 50 years time it could well turn out to be a bit of grit.

      • I just find the claim of the "picture of the century" to be arrogant in the extreme.

        We're only in the second decade of the 21st century. We don't know what will happen in the next 80-someodd years. In 1914, nobody could predict the pictures from the moon.

        For example, what if there's a picture of a "first contact" 50 years from now?

        • In 1914, nobody could predict the pictures from the moon.

          Except for that guy that did [wikipedia.org] and made a film [youtube.com] about it. His images aren't really that similar to the lunar terrain that we considered safe to land on, but 1914 wasn't as backwards as you seem to think. That said, your general point stands: predicting the future is hard. Likely whether or not we have more incredible images in the future, we'll say they're more incredible anyway. Especially if funding levels were commensurate with headlines.

    • The many stars near the black hole shape its silhouette - like the Invisible man is visible if covered in paint. Or maybe the Hawking bh evaporation will help.
      • by Anonymous Coward

        The larger a black hole is, the less intense its Hawking radiation. The one in the galactic centre is too big to emit any detectable Hawking radiation.

        But yes, the silhouette of the black hole should be visible. Somewhat distorted, because light passing near the black hole is bent by gravity, but you can compensate for that.

        • Earth is orbiting the BH in the galactic plane, so wouldn't the ring of fire be seen edge on from our perspective?
          • enhance!

          • maybe... but you seem to be thinking that a black hole is a disk. Super-massive gravity wells, as with other gravity wells, are most likely spherical. If there's matter close enough that are within the galactic plane tolerances, but a bit above or below the well relative to our perspective, there's nothing that says the orbital decay pattern couldn't be in a rotation that we'd see like soap being pulled down a drain as opposed to streaks going across the well's equator.
            • Re: (Score:2, Informative)

              by Anonymous Coward

              The black hole is not a disk. But accretion disks are disks. AKA "ring of fire".

              The angle of the disk matches the rotation of the hole, and the hole should roughly match the rotation of the galaxy overall, and since we're in the galaxy, we'll thus most likely be edge on to the disk.

              • by Anonymous Coward

                This is kind of expected and a good thing. The accretion disk will still be transparent to a lot of signals of interest, but now there is the added benefit of seeing stuff from both the co-rotating and counter-rotating edge of the black hole which will help confirm and measure any rotation. If we were seeing it from some place closer to the poles, it would be much more difficult to see the rotation effects, which otherwise cause a difference in the amount of light that wraps around since it is easier for

              • You overlook one thing: bending of light by the super-intense gravity of the black hole. The "back" side of the accretion disk, i.e. the side turned away from us, emits light. The black hole's gravity will pull that light around the bh and bend it in all possible ways; see Kip Thorne's results found in simulating the Gargantua black hole for the move "Interstellar", he's actually working on a physics / astrophysics paper with his findings. Bending of the accretion disk's light, which the bh will throw forwa
        • by Maritz ( 1829006 )
          The Universe still has an ambient temperature of around 3K I believe. Because of this, no black holes anywhere are actually shrinking, as their temperature is much, much lower than 3K. The ambient temperature of the Universe will not be low enough for black holes to evaporate for a very very long time. I believe we're talking something like ten to the fifty years or more. Also because of this we wouldn't detect hawking radiation because the signal will be utterly swamped by other sources.
          • by Bengie ( 1121981 )
            Yep. Seems a 1 solar mass BH would be 60nk compared to the 2.76k cosmic background radiation. A BH the mass of the Moon would break even.

            Wiki: A black hole of one solar mass has a temperature of only 60 nanokelvin (60 billionths of a kelvin); in fact, such a black hole would absorb far more cosmic microwave background radiation than it emits. A black hole of 4.5 × 1022 kg (about the mass of the Moon) would be in equilibrium at 2.7 kelvin, absorbing as much radiation as it emits.
    • Actually, no, it is not black. In order to have a color, light must reflect off of the object. In a black hole, light does not escape it and therefor it has no color.
      In fact, you cannot see a black hole at all. You would only know it's there because of the objects orbiting the event horizon.

      • by mwvdlee ( 775178 )

        This is semantics. Some people don't think of black and/or white as colors at all. Some people define black as a total absense of light (photons), others as an amount of light below the humanly visible treshold. You seem to define black as the latter, with the addition that atleast some light must be present. In the end, whether a black hole has the color black is a matter for dictionaries, not a matter of scientific fact (unless assuming a scientific definition of what the words "color" and "black" mean).

        • by Bengie ( 1121981 )

          Some people define black as a total absense of light (photons)

          This is a bad definition because it cannot happen in our Universe. All you can do is compare the "brightness" of an object against another object and define the "darker" object as being "black". But no object can be completely void of emitting photons, only less and less of them, approaching zero.

      • by mark-t ( 151149 )
        By its strictest definition, black does not reflect any light either, and so does not qualify as a color either. We can usually see so-called black objects either because they are perhaps just a very dark grey, and are thus still reflecting some amount of light that we can detect, or else in the case of something like Vantablack [scmp.com], because of objects nearby.
        • By its strictest definition, black does not reflect any light either, and so does not qualify as a color either. We can usually see so-called black objects either because they are perhaps just a very dark grey, and are thus still reflecting some amount of light that we can detect, or else in the case of something like Vantablack [scmp.com], because of objects nearby.

          Nanotube/graphene based products like this Vantablack is going to be the new hotness for the next twenty years, then for the fifty years after that it's going to make generations of lawyers very wealthy due to the occupational/environmental exposure cancer claims.

          Call it the 21st century asbestos.

        • Reflective: Black is 100% color

          Transmissive: Black is %0 color

          Depends on the context. As for black holes, maybe it was an unfortunate choice of nomenclature. Should we really be discussing the 'black' part of the name?

    • They'll use flash.
    • +1, wooshie

    • by Anonymous Coward

      Leave the lens cap on, nobody will know.

    • Well, the thing about a Black Hole, its main distinguishing feature, is it's black. And the thing about space, your basic space colour is black. So how are you supposed to see them?

      Actually, in theory, they are not black, but have Hawking radiation that if could be detected accurately would be of some use to us confirming theory. Then there is the radiation given off by the things falling into them. Most black holes probably aren't observable because the region around them is opaque from all the energetic things going on before matter even hits the event horizon. Then, space isn't black, there is cosmic background microwaves, distant galaxies, gas clouds, etc. A black hole will obscur

      • by spitzak ( 4019 )

        The Hawking radiation is very very tiny, and I am pretty certain is impossible to see. Hawking radiation is inversely proportional to the black hole size.

        • The Hawking radiation is very very tiny, and I am pretty certain is impossible to see. Hawking radiation is inversely proportional to the black hole size.

          True, which I why I stated "detected accurately". In fact, for a super massive black hole it should be less than the background radiation from the big bang. Thus, we could expect naked black holes (not singularities) to possibly be a cold spot against the CMB.

  • by vikingpower ( 768921 ) on Friday December 05, 2014 @03:19AM (#48528947) Homepage Journal
    I can not help but wonder at the question: "Will the produced image in any way resemble the black hole depiction in the 'Interstellar' movie ?"
  • I didn't realize that there was still skepticism about the existence of super-massive black holes. If nothing else, we've detected about 200000 quasars - just about the brightest objects in the known universe - each indicating the presence (and proximity) of a supermassive blackhole.

    I thought the general consensus was that there was a supermassive black hole at the centre of every galaxy although only some of these were active, thus showing up as quasars.

    Don't know about this image of the century hype
    • Re: (Score:2, Interesting)

      by Anonymous Coward
      We know supermassive black holes exist.

      We know quasars exist and involve radiation blasted out from the fucktons of matter pouring into early-universe supermassive blackholes.

      What has yet to happen is someone has yet to image the black part of the black hole. The region that's quite literally so dark that light just falls into it. (depending on how thin the accretion disk is, it might not actually be black -- but it's going to be a hell of a lot less energetic than the regions near the disc/equator!).

  • by Le Marteau ( 206396 ) on Friday December 05, 2014 @04:15AM (#48529101) Journal

    > the EHT team is ultimately after to prove the existence of black holes."

    It's already been proven. There is a black hole at the center of the Milky Way galaxy, and it's been named "Sagitarius A"

    Using infrared telesopes, you can "see" stars orbiting the black hole at the center of the galaxy. Orbits of about 28 stars have been observed and using math, the mass of the stars and the required mass of the black hole has been calculated. Only a black hole can account for the kinds of orbits you see those stars doing.

    It is a sight to behold and at first I could not believe it. Watching the stars at the frickin center of the galaxy orbit a black hole is a stunning sight once you truly grok what you are seeing.

    https://www.youtube.com/watch?... [youtube.com]

    Realize that this video is not an artist's intepretation, but is actual imagery of stars orbiting something of immense mass, something which can only be a black hole.

    • by Le Marteau ( 206396 ) on Friday December 05, 2014 @04:27AM (#48529141) Journal

      Correction: It's called "Sagittarius A*" And NASA does not qualify it using terms such as "might be a black hole" or "theorised to be a black hole." They simply call it a "supermassive black hole"

      http://www.nasa.gov/mission_pa... [nasa.gov]

    • by Anonymous Coward

      Stars at the outer edge of the galaxy take the same amount of time to rotate around the galaxy as the inner stars. How can you calculate the mass of the center in this case? If you pick a closer star you will end up with a smaller mass than if you pick an outer star using the same equations.

      Not sure that is proof at all, and from what I remember they recently came up with some new theory that said black holes can't exist (not that this new theory is any better). So I'm not sure there is proof they exist

      • by mark-t ( 151149 )

        Not sure that is proof at all, and from what I remember they recently came up with some new theory that said black holes can't exist (not that this new theory is any better)

        Yeah... a new theory where instead of going through a thorough peer review process first, the person who came up with it simply had a press release about it, giving the theory loads of disproportionate publicity over time-tested theories that explain what we observe far more readily.

        In actuality, that recently announced theory that bla

    • So, it's the Sagittarius A-hole?
    • by pr0t0 ( 216378 )

      Unless those stars are orbiting outside the galactic plane, then I don't believe that is "actual imagery". Maybe it's a representation (based on the data) of what it would look like if you could hover above the galactic plane and look down at the black hole.

      This is why this project seems strange to me. Why image our own galactic center? There's roughly 25,000 light years of dust and stars to see through. Why not image the center of a galaxy that's plane is perpendicular to us?

      • > There's roughly 25,000 light years of dust and stars to see through.

        You're right... it would be impossible to view those stars using the optical spectrum. However, the scientists in this case, and for the multi-year time-lapse loop I linked to used radio waves which were unaffected by dust. One might think that interposing stars would block out the view (after all, the view is sideways through the "platter" of the galaxy) but given the far separation of the stars, the view is not blocked even at such

      • > Why not image the center of a galaxy that's plane is perpendicular to us?

        Another factor: on that video I linked, the scale on those images is 10 light days. I don't think modern astronomy can resolve individual stars on that fine a scale, which would be required to produce the same effect while viewing another galaxy.

        That's another thing that makes that image amazing to me... how close those stars are. 10 light days is nothing, cosmically speaking.

    • https://www.youtube.com/watch?... [youtube.com]

      Realize that this video is not an artist's intepretation, but is actual imagery of stars orbiting something of immense mass, something which can only be a black hole.

      Do you know the time scale of this video? Are these stars orbiting in hours, days, years?

  • by Prune ( 557140 ) on Friday December 05, 2014 @04:59AM (#48529237)
    The surface of the collapsing star takes an infinite time to cross the event horizon form the point of view of an outside observer? No star which has collapsed has yet turned into a black hole, and no one will at a finite age of the outside universe. The only way to prove the existence of a black hole is to fall through an event horizon. Of course, then you only prove it for yourself, and cannot tell anyone else.
    • That's nitpicking (Score:5, Insightful)

      by amaurea ( 2900163 ) on Friday December 05, 2014 @07:55AM (#48529695) Homepage

      The surface will get very close to the apparent horizon very quickly though, and after that it will be so redshifted that it looks just like one of the idealized black hole solutions, and will be indistinguishable from one to any observer. It will be just as black, just as compact and just attractive, and still deserves to be called a black hole. When people say "black hole" they don't necessarily mean "Schwartzchild black hole" or "Kerr black hole".

    • by MrKevvy ( 85565 )

      I'm glad this long-overlooked idea is finally being remembered. It does lead to two further conclusions of course: how can these frozen collapsing stars have spin? And how can they have magnetic fields or (detectable) electric charge?

      It doesn't seem they could have either, so all the physics done on rotating and/or charged/magnetic black holes with real singularities seems to be making the rather large assumption that there are any that were formed at the birth of the universe. They can't form now so quite

    • by mark-t ( 151149 )
      I might suggest that you may only be correct about your assumptions in that no star which has collapsed has yet turned into a singularity... all that is required for a black hole is sufficiently bending space in the region of a mass such that no straight line near the mass, and where it is within some finite volume as measured from outside of that region, ever leaves said vicinity of the mass. It is entirely possible that the entire universe may be within a black hole, which itself is inside of another, m
  • Here, I got your work cut out for you:

    https://www.google.com/search?site=&tbm=isch&source=hp&biw=1440&bih=811&q=black+hole&oq=black+hole&gs_l=img.3..0l10.1410.3802.0.4788.10.9.0.1.1.0.267.1084.0j2j3.5.0.msedr...0...1ac.1.58.img..4.6.1087.Tj8XnhV53ww
    • by Anonymous Coward

      Yes, fuck yeah. Science is a waste of money, build more churches.

  • Business Insider? (Score:5, Informative)

    by jbmartin6 ( 1232050 ) on Friday December 05, 2014 @08:20AM (#48529795)
    What use is a link to a science article on Business Insider? Here is the EHT project home page [mit.edu] It seems the goals of the project are a lot more interesting than simply proving black holes exist.
  • by NixieBunny ( 859050 ) on Friday December 05, 2014 @09:42AM (#48530275) Homepage
    If you have any actual questions about how it's done. I might be able to shed some light on what this thing is. It involves masers and 4K fridges and some rather high IF frequencies.
    • When will observations start? How long will they last? When can we expect to see results on arXiv? How well will the fourier plane be covered (will you still need telescopes in the middle of nowhere to join/be built)? What will the spatial and temporal resolution be? Are there any important astrophysical foregrounds that could mess things up (blurring by plasma sheaths is something I think I've heard mentioned)? How are they handled? Did you know from the beginning that ALMA would join? Can you expect any o

      • I work on the engineering side, rather than the project management side. The two EHT telescopes that I work on are in Arizona, although I build some of the hardware that's being taken to the South Pole Telescope. It's getting improved to be a part of the EHT. One of the Arizona telescopes is a prototpye ALMA antenna that we just moved here from New Mexico last year, and got working a month ago.

        Observations are typically done in March/April. This gives good weather at the many sites involved. The typical
        • The two EHT telescopes that I work on are in Arizona, although I build some of the hardware that's being taken to the South Pole Telescope. It's getting improved to be a part of the EHT. One of the Arizona telescopes is a prototpye ALMA antenna that we just moved here from New Mexico last year, and got working a month ago.

          That's intereting. I didn't know that the EHT worked at SPT-relevant frequencies. I work on data analyis for the Atacama Cosmology Telescope, a very similar telescope to SPT, and a neighbor of ALMA. So I've seen the ALMA telescopes up close several times.

          Observations are typically done in March/April. This gives good weather at the many sites involved.

          Isn't the weather often bad at the ALMA site in that period? In ACT we've used that period for maintenance.

          The typical run is a week, and they try to get several 10-minute recordings during that time period. The data is recorded at 1 Gbyte/sec onto banks of hard drives, then shipped by FedEx to MIT for correlation. (I don't know if a FedEx truck makes it to the South Pole every day.)

          That's a lot of hard drives! Is that the aggregate data rate for all the telescopes, or just for SPT?

  • Supermassive Black Hole At The Centre Of The Galaxy May Be A Wormhole In Disguise, Say Astronomers https://medium.com/the-physics... [medium.com]
    • That's a fascinating article, but you won't find many astrophysicists who would bet on it being correct (this probably includes the authors). Traversable wormholes are unstable without large amounts of negative mass, and we have no reason to believe that such exotic matter even exists. And if one is willing to assume that these wormholes have been there since the beginning of the universe in order to explain the presence of compact massive bodies in the center of every galaxy, then you might as well assume

  • by Berkyjay ( 1225604 ) on Friday December 05, 2014 @12:01PM (#48531469)
    How can anyone argue that black holes don't exist? I mean we've tracked stars at the center of our galaxy orbiting something at extreme speeds. We've never seen electrons, but we've all but confirmed their existence by how they interact with our environment.
    • It is possible quantum mechanics prevents formation of a black hole, instead there could be a form of degenerate or exotic matter. We don't have a useable theory of quantum gravitation yet to know what happens when the realms of GR and QM overlap

  • I created the Event Horizon to reach the stars, but she's gone much, much farther than that. She tore a hole in our universe, a gateway to another dimension. A dimension of pure chaos. Pure... evil. When she crossed over, she was just a telescope. But when she came back... she was alive! Look at her, Miller. Isn't she beautiful?

The 11 is for people with the pride of a 10 and the pocketbook of an 8. -- R.B. Greenberg [referring to PDPs?]

Working...