LIGO Detects Gravitational Waves

00:05:26
https://www.youtube.com/watch?v=B4XzLDM3Py8

Ringkasan

TLDRLIGO, the Laser Interferometer Gravitational Wave Observatory, is a pioneering experiment aimed at detecting gravitational waves, ripples in spacetime predicted by Einstein a century ago. The project, supported by the National Science Foundation, involves two observatories functioning simultaneously with precise measurements using lasers and massive mirrors. Despite initial skepticism due to the minuscule effect of these waves, LIGO has successfully detected gravitational waves stemming from the merger of two black holes. This groundbreaking discovery marks a new era in astrophysics, comparable to Galileo's use of the telescope, revealing profound insights into the universe.

Takeaways

  • 🌌 LIGO detects gravitational waves, extending Einstein's theory.
  • 🔭 It's like Galileo's telescope moment for astrophysics.
  • 🚀 Two massive observatories work in tandem to capture ripples in spacetime.
  • 📏 Achieving the precision required was a technological marvel.
  • 💡 LIGO is funded by the National Science Foundation.
  • 👨‍🔬 Initially, many doubted the feasibility of detecting these waves.
  • 🔥 First successful detection involved merging black holes.
  • 🔍 MIT played a key role in developing data analysis techniques.
  • 🎭 The project was bold and visionary from the start.
  • 📜 Einstein would have been amazed by the confirmation of his predictions.

Garis waktu

  • 00:00:00 - 00:05:26

    LIGO, the Laser Interferometer Gravitational Wave Observatory, consists of two observatories working in tandem. It uses advanced lasers and massive, pure mirrors to detect gravitational waves, which was a high-risk and costly experiment backed by the NSF. Originally conceived in the 70s and 80s, the project was considered bold and visionary. Despite skepticism about detecting such waves due to their minute effect size, proponents persisted. Gravitational waves, first predicted by Einstein, involve tiny perturbations in spacetime. Detection relied on the principle that these waves stretch and compress space, leading to the development of kilometer-scale observatories. Overcoming technological challenges, MIT contributed by developing techniques and data analysis methods. This effort led to the detection of waves from merging black holes, marking the start of a new astronomical era, much like Galileo's telescope, unveiling nature's secrets anew. It's celebrated as a monument to human ingenuity and Einstein's enduring legacy.

Peta Pikiran

Video Tanya Jawab

  • What does LIGO stand for?

    LIGO stands for the Laser Interferometer Gravitational Wave Observatory.

  • How long are the LIGO arms?

    The arms of the LIGO interferometer are about 2.5 miles (4 kilometers) long.

  • What was the biggest challenge in detecting gravitational waves?

    The biggest challenge was achieving the precision required, as the effect of gravitational waves is incredibly small, about 1,000th the diameter of a proton.

  • Who funded the LIGO project?

    LIGO was funded by the National Science Foundation (NSF).

  • What did Einstein predict about gravitational waves?

    Einstein predicted gravitational waves as dynamical perturbations in the fabric of spacetime about 100 years ago.

  • Why is the detection of gravitational waves compared to Galileo's telescope?

    Detecting gravitational waves is seen as a monumental step in the study of the universe, much like Galileo's first use of the telescope.

  • What has LIGO observed?

    LIGO has observed gravitational waves resulting from two black holes merging to form a larger black hole.

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Gulir Otomatis:
  • 00:00:00
  • 00:00:00
    LIGO stands for the Laser Interferometer Gravitational
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    Wave Observatory.
  • 00:00:04
  • 00:00:07
    LIGO is really two observatories that work in unison, in tandem.
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    The LIGO interferometer has arms that
  • 00:00:14
    are about 2 and 1/2 miles long, 4 kilometers.
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    We have a laser.
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    The laser produces the purest light you can possibly make.
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    It produces light that's so coherent
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    that it's capable of detecting gravitational waves.
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    We have these very massive mirrors.
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    They weigh 40 kilograms, which is about 88 pounds.
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    They're about this thick.
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    And they're just the purest material you can imagine.
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    The NSF, of course, had to be the source
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    of funding for anything that would be as expensive as this.
  • 00:00:44
    This was going to be a very high-risk experiment.
  • 00:00:49
    It was from its very inception.
  • 00:00:52
    If you think about this in the '70s and '80s,
  • 00:00:55
    I'm amazed at how bold it was to do this, and visionary.
  • 00:01:02
    It was bold and visionary.
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    There's no other way to describe it.
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    NSF management, the National Science Board,
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    they had to really step up to that.
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    And they had a lot of discussions,
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    brought in a lot of experts.
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    There was great debate going on.
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    But in the end, the people who thought it could be done
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    won the day.
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    And they went after it.
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  • 00:01:32
    Gravitational waves were predicted by Einstein
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    about 100 years ago.
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    And they are dynamical perturbations
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    in the fabric of spacetime, ripples in spacetime,
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    if you will.
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    A ripple in the fabric of space and time the same way
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    as a ripple on a pond is a ripple
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    in the shape of the surface of the water.
  • 00:01:52
  • 00:01:55
    Nobody really believed that you could ever detect them,
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    because the size of the effect is so small--
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    1,000th the diameter of a proton.
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    Even Einstein himself never thought
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    a detection would be possible.
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    I tried to do this back in the 1960s when I was a student.
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    We couldn't make any progress.
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    We didn't have the technology.
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    The idea was extremely simple.
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    And it turns out to be the basis of LIGO.
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    What the gravitational wave does is it stretches space this way
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    and compresses space that way.
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    So you exploit that property.
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    Put one object here and another object over there.
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    And let the gravitational wave go through that system.
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    And it will change the space between these
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    by contracting that one and extending that one.
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    And I came to the conclusion that if you
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    made this long enough, if you didn't make
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    it a little pipsqueak thing like this, but you made it
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    sort of kilometer-scale, you could probably
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    get these extremely precise measurements.
  • 00:03:01
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    Nobody had ever made something like this before.
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    So there's a lot of technological challenges
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    that needed to be overcome.
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    The precision that was required was just amazing,
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    mind boggling.
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    The MIT Group has typically concentrated
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    on developing new techniques to make the instruments work
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    and then to work on, also, data analysis algorithms
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    that are well-informed by the understanding
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    of the instrument.
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    We have observed gravitational waves
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    from two black holes forming a larger black hole.
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    Two black holes merging together, literally,
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    nearly the speed of light to produce a bigger black hole.
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    How cool is that?
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    I said, holy mackerel.
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    This is the beginning of a whole new way
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    of studying the universe.
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    It's monumental.
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    It's like Galileo using the telescope for the first time.
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    Every time we have pointed a new instrument into the sky,
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    nature has revealed secrets to us
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    that we haven't known before.
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    And so I feel very confident that this is just
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    the beginning of such an era for gravitational wave
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    observations, as well.
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    Who knows what we'll see?
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    I would love to see Einstein's face
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    if he could read this article that we just put out.
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    I mean, he would have been as dumbfounded as we are.
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    Because it's a wonderful proof that all
  • 00:04:34
    of this incredible stuff, the strong-field gravity,
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    is in his equations.
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    Just imagine that.
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    To me, that's a miracle that that happened-- man's thinking
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    and also all the elegance not only in the theory,
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    but the elegance in the experiment.
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    I mean, that is a human endeavor that, I think,
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    everybody in the world should be proud of.
  • 00:04:55
  • 00:04:58
    I had to tell you that.
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  • 00:05:02
    [MUSIC PLAYING]
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Tags
  • LIGO
  • Gravitational Waves
  • Einstein
  • NSF
  • Astrophysics
  • Black Holes
  • Spacetime
  • Laser Technology
  • Interferometer
  • Scientific Discovery