30. Gravitational Waves I: Introduction (General Relativity)

00:59:15
https://www.youtube.com/watch?v=kIBdtbCszB0

摘要

TLDRThis lecture discusses the fascinating world of gravitational waves, emphasizing their significance in observing strongly gravitating systems like black holes and neutron stars. After introducing gravitational wave theory and the challenges posed by Einstein's nonlinear equations, the lecture details the first gravitational wave detection in 2015 by LIGO, a network of detectors in the U.S. followed by other significant detections involving VIRGO in Italy. As the author delves into the future of gravitational wave astronomy, the lecture introduces impending projects, like the LISA space mission, highlighting an international effort led by ESA and NASA, and new ground-based detectors such as KAGRA in Japan and Indigo in India. Cutting through the technical complexities, the lecturer illustrates how gravitational waves work using Fermi normal coordinates and discusses the peculiar nature of these waves, evident in their transverse effects and unique polarization patterns. The understanding of these waves marks a monumental leap in modern astrophysics, promising new insights into the cosmos.

心得

  • 🌌 Gravitational waves enable direct observation of massive cosmic events like black hole mergers.
  • 🌍 The LIGO detectors in the U.S. first observed gravitational waves in 2015.
  • 🇮🇹 The VIRGO detector in Italy collaborates with LIGO for enhanced observation capabilities.
  • 📡 Future detectors like KAGRA and Indigo will improve the sensitivity of gravitational wave observations.
  • 🛰️ The LISA mission will explore gravitational waves in space, expanding observational capabilities.
  • 💡 Gravitational waves are complex due to nonlinear Einstein equations and require approximation methods for their description.
  • ⚙️ Fermi normal coordinates are used to simplify observations near gravitational wave sources.
  • 🔧 Technological advancements play a crucial role in improving gravitational wave detector sensitivities.
  • 🌀 Plus and cross polarization are patterns created by gravitational waves as they pass through.
  • 🌐 The international effort in gravitational wave research is set to expand with multiple global collaborations.

时间轴

  • 00:00:00 - 00:05:00

    The lecture introduces gravitational waves and highlights the significance of detecting them. The first detection was in 2015, of two black holes merging, observed by LIGO detectors in the US. Subsequent notable detections including one in 2017 with LIGO and VIRGO detectors involve black hole and neutron star mergers, also observed in gamma-ray bursts.

  • 00:05:00 - 00:10:00

    Ground-based detectors like LIGO and VIRGO are supported by others worldwide, such as GEO in Germany and TAMA in Japan. New detectors, KAGRA in Japan and INDIGO in India, are being constructed. Efforts are underway for a detector in Australia. These instruments all have large scale interferometer designs.

  • 00:10:00 - 00:15:00

    These ground-based detectors are sensitive to gravitational waves from massive astronomical mergers. A major project, the LISA mission, aims to place a gravitational wave detector in space with satellites forming a large interferometer, sensitive to a different range of frequencies suitable for different cosmic events.

  • 00:15:00 - 00:20:00

    Gravitational waves are described as fluctuations in spacetime curvature, propagating at light speed. Their complex mathematical description involves Einstein's nonlinear equations and gauge freedom in general relativity, affecting the interpretation of metric fluctuations.

  • 00:20:00 - 00:25:00

    Weak gravitational waves from distant events are perturbations on flat spacetime, manageable despite the complexities of general relativity. Another challenge is gauge freedom, the ability to change spacetime coordinates, which complicates detecting genuine spacetime fluctuations.

  • 00:25:00 - 00:30:00

    An illustrative example shows a metric perturbation resembling a wave due to coordinate choices rather than representing a gravitational wave. The mathematical exercise involves flat spacetime in Minkowski coordinates with imposed oscillations, demonstrating the need for careful distinction in analysis.

  • 00:30:00 - 00:35:00

    True gravitational waves, unlike coordinate-induced fluctuations, meet Einstein's equations requirements. They are small perturbations behaving like plane waves, propagating in a direction with a certain amplitude and solve approximately the vacuum Einstein equations.

  • 00:35:00 - 00:40:00

    The lecture outlines the complexities of deriving geodesic equations with perturbed metrics, demonstrating how particles fit within these perturbations. Solutions show how particles oscillate within fields, aligning with expected gravitational wave impacts, highlighting the challenges of mathematical modeling.

  • 00:40:00 - 00:45:00

    A transformation to Fermi normal coordinates simplifies the curved spacetime description local to an observer, allowing them to perceive themselves within special relativity rules, and relating particle movements to proper separations, applied here with simple examples in Minkowski space.

  • 00:45:00 - 00:50:00

    Through Fermi normal coordinates derived, an observer can see the measurable effect of gravitational waves on test masses, with oscillations representing physical impacts of waves. This setup provides observable evidence of wave effects in a tangible manner, demonstrating their transverse nature.

  • 00:50:00 - 00:59:15

    The lecture concludes with a summation of demonstrating a gravitational wave example, emphasizing transverse effects and the so-called 'plus polarization'. The next lecture plans to delve into deriving both 'plus' and 'cross' polarization states, expanding on their characteristics and propagation.

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思维导图

视频问答

  • What are gravitational waves?

    Gravitational waves are fluctuations in the curvature of spacetime that produce oscillatory tidal effects, propagating at the speed of light.

  • When was the first gravitational wave detected?

    The first gravitational wave was detected in September 2015 by the LIGO detectors.

  • Where are the LIGO detectors located?

    The LIGO detectors are located in Washington and Louisiana, USA.

  • What is the LISA mission?

    The LISA mission aims to place gravitational wave detectors in space, led by the European Space Agency and NASA.

  • What kind of events can gravitational wave detectors observe?

    They can detect events like the merger of black holes and neutron stars.

  • What challenges are involved in describing gravitational waves mathematically?

    Gravitational waves are difficult to describe mathematically due to the nonlinear nature of Einstein's equations and gauge freedom in general relativity.

  • What is the difference between plus and cross polarization in gravitational waves?

    Plus polarization distorts a ring of test masses into a plus pattern, while cross polarization distorts it into a cross pattern.

  • What are Fermi normal coordinates?

    Fermi normal coordinates are a local coordinate system used around an observer in free fall to simplify the description of spacetime geometry.

  • What is the role of other detectors like GEO and TAMA?

    Although they have lower sensitivity, GEO and TAMA played important roles in the technological development of gravitational wave detection.

  • What are the expected future advancements in gravitational wave detectors?

    New detectors like KAGRA in Japan and Indigo in India are expected to have enhanced sensitivities, with plans also to establish detectors in Australia.

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  • 00:00:05
    >> This is the first of several lectures on gravitational waves.
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    [ Typing ]
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    The exciting thing about gravitational waves is that they allow us
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    to make direct observations of strongly gravitating systems.
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    [ Typing ]
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    As you probably know, we have a growing network of ground-based gravitational wave detectors
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    that have recently detected a number of collisions among black holes and neutron stars.
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    [ Typing ]
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    The first gravitational wave detection occurred in September of 2015.
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    [ Typing ]
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    This event consisted of two black holes orbiting each other, then spiraling together
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    and merging to form a single black hole.
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    Now this system originally consisted of a 36 solar mass black hole,
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    and a 29 solar mass black hole, and they merged to form a 62 solar mass black hole plus
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    about three solar masses worth of gravitational waves.
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    [ Typing ]
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    So let me complete my picture here by showing some gravitational waves.
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    [ Typing ]
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    This first detection was made by the LIGO detectors, which are in the United States.
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    [ Typing ]
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    There are actually two detectors; one in the state of Washington --
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    [ Typing ]
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    -- which is in the Northwestern part of the country, and the others in the state
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    of Louisiana, which is in the south central part of the country.
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    Since this time, there have been a number of other detections.
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    One of the most notable occurred in August of 2017.
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    This was a 25 solar mass black hole --
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    [ Typing ]
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    -- merging with a 30 solar mass black hole.
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    And this was seen not only by the two LIGO detectors,
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    but also by the VIRGO detector, which is located in Italy.
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    Then just a few days later, also in August of 2017 --
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    [ Typing ]
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    -- the two LIGO detectors and the VIRGO detector detected a binary neutron star merger.
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    And this event was also seen in the electromagnetic spectrum as a gamma-ray burst.
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    [ Typing ]
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    In addition to the LIGO and VIRGO detectors, there are a number of other detectors
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    around the world that were not sensitive enough to see any of these events,
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    and they probably won't see any future events either,
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    but these instruments played an important role in the development
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    of the technology needed to detect gravitational waves.
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    Among these other detectors --
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    [ Typing ]
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    -- the most notable are GEO in Germany --
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    [ Typing ]
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    -- and TAMA in Japan.
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    [ Typing ]
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    Currently plans are underway for the construction
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    of several new detectors whose sensitivities will equal or exceed the sensitivities
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    of the current LIGO and VIRGO detectors.
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    These new detectors include --
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    [ Typing ]
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    -- KAGRA, which is in Japan.
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    And might be online is, early as 2020.
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    [ Typing ]
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    And Indigo --
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    [ Typing ]
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    -- which is in India.
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    And construction is expected to begin around 2020.
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    [ Typing ]
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    There's also a lot of interest and serious discussions
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    about placing gravitational wave detector in Australia in the near future.
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    [ Typing ]
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    Now all of these detectors that I've mentioned so far are ground-based instruments.
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    [ Typing ]
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    They're large scale interferometers.
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    [ Typing ]
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    They have arm lengths --
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    -- in the range of three to four kilometers and their sensitivities --
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    [ Typing ]
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    -- are in the range of tens to thousands of Hertz.
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    [ Typing ]
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    So these instruments are all sensitive to the gravitational waves from events like the merger
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    of approximately equal mass black holes or neutron stars.
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    [ Typing ]
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    One of the most exciting plans for gravitational wave physics is the LISA mission,
  • 00:06:00
    which will place the gravitational wave detector in space.
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    [ Typing ]
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    So this is the LISA mission.
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    It's being led by the European space agency with input also from NASA in the United States.
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    Now the LISA detector will consist of satellites working together as a large interferometer
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    with arm lengths of millions of kilometers --
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    [ Typing ]
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    -- and a sensitivity --
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    [ Typing ]
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    -- in the range from 10 to the minus 4 to 10 to the minus 1 Hertz.
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    This is the appropriate frequency range for an event
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    such as the inspiral of a roughly solar mass --
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    [ Typing ]
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    -- black hole or neutron star into a supermassive black hole.
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    [ Typing ]
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    Currently, the expected launch date for the lease submission is around 2034.
  • 00:07:29
    So what is a gravitational wave?
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    [ Typing ]
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    I don't have a simple one sentence answer to that question,
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    but in a few sentences, it's a fluctuation --
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    [ Typing ]
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    -- in the curvature of spacetime.
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    [ Typing ]
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    It produces oscillatory tidal effects.
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    [ Typing ]
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    So these are the world lines of two freely falling particles.
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    These particles are an accelerated, but the space in between them is expanding
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    and contracting due to the passing gravitational wave.
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    And finally, I would add to this description that the fluctuations --
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    [ Typing ]
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    -- propagate through space --
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    -- at the speed of light.
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    [ Typing ]
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    Now, gravitational waves are a bit complicated to describe mathematically --
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    [ Typing ]
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    -- and this is for two main reasons.
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    The first reason is the Einstein equations are nonlinear.
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    [ Typing ]
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    As a result, we can't write down exact solutions in most cases;
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    we have to work with solutions that are only approximate.
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    [ Typing ]
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    And another consequence of the nonlinearity is that waves can't be superimposed.
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    [ Typing ]
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    But what we can do in spite of this nonlinearity is develop the theory of a weak waves
  • 00:09:53
    as small perturbations of flat spacetime.
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    [ Typing ]
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    So weak gravitational waves as perturbations --
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    [ Typing ]
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    -- on flat spacetime.
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    And this should be sufficient for applications in astrophysics
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    where the gravitational waves we detect from distant cosmological events are very, very weak.
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    So this is okay for applications in astrophysics.
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    [ Typing ]
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    Now, the second main reason why gravitational wave theory is complicated is
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    because general relativity contains a large gauge freedom.
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    [ Typing ]
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    Now, what I mean by gauge freedom
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    in this context is the freedom to change spacetime coordinates.
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    [ Typing ]
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    So change of spacetime coordinates doesn't actually change the spacetime geometry.
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    The term gauge comes from electromagnetism and it's also used
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    in Yang-Mills theory's in particle physics.
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    And in this context of gravitational wave physics, we often refer to this freedom
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    of changing spacetime coordinates as a gauge freedom.
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    In practice, this is an important issue because we need to know how to interpret the metric
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    to understand whether fluctuations are coming from the spacetime geometry
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    or from the choice of coordinates.
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    [ Typing ]
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    So fluctuations in the metric could be coming from the geometry --
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    [ Typing ]
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    -- or from the choice of coordinates --
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    [ Typing ]
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    -- or of course a mixture of both.
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    Let me give you an example of this.
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    [ Typing ]
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    Let's take flat spacetime in Minkowski coordinates.
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    [ Typing ]
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    So let's -- let those coordinates be t bar, x bar, y bar and c bar.
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    So the metric is minus dt bar squared plus the dx bar squared plus dy bar squared plus dz
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    bar squared.
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    And now let's make a change of coordinates.
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    So the new coordinates are defined by t bar equals t, x bar equals x, y bar equals y
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    and z bar equals z minus a divided by Omega times cosine of Omega times t minus z.
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    In this expression, Omega is an angular frequency and a is an amplitude,
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    it's a dimensional amplitude, and we want to think of this as being very small.
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    So this coordinate transformation is close to the identity.
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    Now let's work out the metric and these new unbarred coordinates.
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    You have ds squared equals minus dt bar squared, but t bar is equal to t,
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    so this is just minus dt squared.
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    Likewise, we have plus dx squared plus dy squared plus dz bar is dz plus a time sine
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    of Omega times t minus z times dt minus dz, and all of that is squared.
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    Now let's simplify this.
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    We have minus dt squared plus dx squared plus dy squared.
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    Then squaring this term, we have dz squared, we have the cross terms which are 2a times sine
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    of Omega t minus z times dz times dt minus dz.
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    And then we have the term that comes from squaring this term
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    and that term is proportional to a squared.
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    [ Typing ]
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    And remember a is very small, so we'll drop these terms.
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    So putting this together we have minus dt squared plus dx squared plus dy squared plus,
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    now the dz squared terms, we have 1 times dz squared minus 2a sine
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    of Omega t minus z times dz squared.
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    And then we also have these terms dz times dt that's plus 2a sine Omega t minus z times dtdz.
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    And there are higher order terms in a that we're dropping.
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    Now because a is small, this metric is close to the Minkowski metric.
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    In fact, we can write the metric as a mu nu plus a small perturbation, which we'll call h mu nu.
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    So h is a perturbation of the Minkowski metric --
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    [ Typing ]
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    -- which is proportional to the small amplitude a. Let me write down h explicitly.
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    From the line element here we have h mu nu as a matrix equals zero zero zero a sine
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    of Omega t minus z. And the second row was all zeros, third row is all zeros,
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    and we have a times sine of Omega t minus z zero zero and finally minus 2a times sine
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    of Omega t minus z. So this metric looks a lot like what one might think
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    of as a gravitational wave, but it's not a gravitational wave.
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    [ Typing ]
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    It's not.
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    [ Typing ]
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    The oscillations in the metric are just coming from oscillations in the coordinates.
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    Remember, this is just flat spacetime written in a new set of coordinates.
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    We can see what's happening if we recall the coordinate transformation was z bar equals z
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    minus a over Omega times cosine of Omega times t minus z. And now remember t was equal to t bar,
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    so we can also write this as t bar minus z. And in this expression,
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    z bar and t bar are Minkowski coordinates for flat spacetime.
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    So if we plot a Minkowski diagram, this is the t bar axis and this is the z bar axis.
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    Then the curves with constant z bar are of course just straight lines.
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    [ Typing ]
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    So this is constant z bar.
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    Now what about the curves with constant z?
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    For example, let's take z equals zero and plot that curve on this t bar z bar diagram.
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    So if z is equal to zero, there's zero here, zero here,
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    we have z bar at t bar equals zero z bars minus a over Omega.
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    So right here, and then as t bar increases --
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    -- we get a sine or cosine wave like this.
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    So this is the z equals zero curve.
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    Now let's pick another value of z, say pi over 2.
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    So we start shifted to the right by pi over 2 and also shifted in phase upward by pi over 2.
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    So that curve would look something like --
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    -- this. So this is the pi over 2 curve.
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    So the lesson from this example is that we need to be careful.
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    This metric with this perturbation on flat spacetime is not a gravitational wave,
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    the wave like elements in this perturbation just come from a choice of wavy coordinates.
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    In later lessons, I'll go through the analysis of the gauge freedom for perturbations
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    on flat spacetime and show how we can restrict the choice of coordinates
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    to eliminate solutions like this one.
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    For now, I think it will be useful to put these issues aside and show you a metric perturbation
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    that does represent a gravitational wave.
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    So here's the example that I want to use.
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    [ Typing ]
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    The metric is close to flat spacetime
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    with Minkowski coordinates, and the perturbation is h mu nu.
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    And h mu nu written as a matrix is zero zero zero zero zero times a sine
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    of Omega t minus z zero zero zero zero than minus a sine
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    of Omega t minus z zero then the last row is all zeros.
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    This metric represents a plane wave --
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    [ Typing ]
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    -- propagating in the z direction.
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    [ Typing ]
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    Now this dimensional amplitude a, we're assuming is small, much smaller than one.
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    And you can check that this metric satisfies the vacuum Einstein equations.
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    [ Typing ]
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    So that would be g mu nu equals zero up to linear through linear order in a.
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    So there are 10 error terms of order a squared.
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    So that just means this is an approximate solution
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    of Einstein's equations, not an exact solution.
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    Now the first thing I'd like to do with this metric is to compute the geodesics equations.
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    [ Typing ]
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    For that purpose we need to Christoffel symbols.
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    So gamma mu alpha beta is 1/2g upper mu nu partial alpha g beta nu plus partial beta g
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    alpha nu minus partial nu g alpha beta.
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    So we're going to need the inverse metric.
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    What is that?
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    Well, let's recall the metric itself is the flat metric plus a perturbation h.
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    So we expect the inverse metric to also be close to the flat metric.
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    So g mu nu is a mu nu plus some small perturbation, let's call it k upper mu nu.
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    And now we want to define k such that g mu nu g upper nu sigma is equal to delta sigma mu.
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    So let's work that out.
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    That's g mu nu plus h mu times ADA upper nu sigma plus k nu sigma.
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    And now ADA times ADA gives delta mu sigma.
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    We have a term ADA times k that's ADA mu nu k nu sigma.
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    We have this term h times ADA h mu nu ADA nu sigma.
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    And then we have a term h times k, but that's second order in small quantities.
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    [ Typing ]
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    So we'll ignore that term.
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    And now all of this must equal delta mu sigma.
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    So that tells us --
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    [ Typing ]
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    -- that ADA mu nu k nu sigma equals minus h mu nu ADA nu sigma.
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    And now if we multiply this equation by the inverse of the ADA, say ADA Rho mu,
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    so we're multiplying this equation by ADA Rho mu,
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    we find k Rho sigma equals minus ADA Rho mu h mu nu ADA mu sigma.
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    So this is k, the perturbation of the inverse metric.
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    And for notational convenience we're going
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    to define this combination ADA inverse times h times ADA inverse as,
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    here's the minus sign, as h upper Rho sigma.
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    So here I'm using for the first time the convention that indices
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    on h the metric perturbation are raised and lowered
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    with the flat metric, with ADA and it's inverse.
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    So now we can write the inverse metric as ADA mu nu minus h mu nu.
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    And notice also when we insert the metric in here,
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    all the terms involving derivatives with ADA vanish.
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    So Christoffel will symbols become gamma mu alpha beta equals 1/2 ADA mu nu minus h mu nu
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    times partial alpha h beta nu plus partial beta h alpha nu minus partial nu h alpha beta.
  • 00:24:37
    For now, we're just carrying out our calculations
  • 00:24:39
    to linear order in small quantities.
  • 00:24:42
    Remember h is proportional to the small amplitude a
  • 00:24:46
    and so also derivatives of h are small quantities.
  • 00:24:50
    So in this expression, h times derivatives of h are second order, and we'll ignore those terms.
  • 00:24:56
    So we'll write gamma equals 1/2 ADA mu nu partial alpha h beta nu plus partial beta h
  • 00:25:08
    alpha nu minus partial nu h alpha beta.
  • 00:25:12
    Then there are second order terms that we'll ignore.
  • 00:25:17
    Now let's recall the mu nu zero components of h are hxx, which was equal to a times sine
  • 00:25:28
    of Omega t minus z. And that was also equal to minus hyy,
  • 00:25:35
    and all the other components of h are zero.
  • 00:25:37
    So when we compute Christoffel symbols, the only possible answers we can have or either zero
  • 00:25:43
    or plus or minus 1/2 times the derivative of this function.
  • 00:25:48
    So let me just skip to the results.
  • 00:25:51
    The Christoffel symbols that equal plus 1/2 a Omega times cosine
  • 00:25:57
    of Omega t minus z are gamma txx, gamma zxx, gamma xtx, and gamma yzy,
  • 00:26:06
    and of course also gamma xx, gamma yyz,
  • 00:26:11
    since the Christoffel symbols are symmetric in their lower indices.
  • 00:26:21
    And the Christoffel symbols that are equal to minus this same quantity --
  • 00:26:30
    [ Typing ]
  • 00:26:33
    -- are gamma tyy, gamma zyy, gamma xzx, and gamma yty,
  • 00:26:39
    and all the other Christoffel symbols vanish.
  • 00:26:47
    And now for the geodesic equations.
  • 00:26:54
    [ Typing ]
  • 00:27:01
    Remember the geodesic equation is x mu double dot plus gamma mu alpha beta x dot alpha x dot
  • 00:27:10
    beta equals zero.
  • 00:27:14
    So for the zero component for t component, you have t double dot plus,
  • 00:27:20
    you have the nonzero Christoffel symbols with an upper t index, that's txx and tyy.
  • 00:27:28
    So we insert those in here we obtain 1/2a Omega times cosine
  • 00:27:35
    of Omega t minus z times x dot squared minus y dot squared and that's equal to zero.
  • 00:27:45
    So the x component, we have x double dot plus a Omega times cosine
  • 00:27:52
    of Omega t minus z times the [inaudible] Christoffel symbols are,
  • 00:27:58
    have lower indices tx and zx.
  • 00:28:01
    So this is times t dot x dot minus z dot x dot equals zero.
  • 00:28:09
    For the y component it's y double dot plus a Omega cosine
  • 00:28:16
    of Omega t minus z times z dot y dot minus t dot y dot equals zero.
  • 00:28:29
    And finally, for the z component, we have z double dot plus 1/2a Omega times cosine
  • 00:28:38
    of Omega t minus z times x dot squared minus y dot squared equals zero.
  • 00:28:47
    So these equations are fairly complicated, but there's one family of solutions
  • 00:28:51
    that is fairly easy to identify --
  • 00:28:53
    [ Typing ]
  • 00:29:00
    -- and it's the following.
  • 00:29:02
    Remember, dot stands for derivative with respect to proper time.
  • 00:29:05
    So one solution is t equals Tao [phonetics] proper time x equals x naught some constant,
  • 00:29:14
    y equals y naught and z equals z naught, where these are all constants.
  • 00:29:20
    [ Typing ]
  • 00:29:24
    And of course we could add a constant to t to tell here as well.
  • 00:29:28
    You can verify just by inspection that these world lines satisfy the geodesic equations.
  • 00:29:37
    So all of these terms with double dot vanish,
  • 00:29:40
    and also all of these other terms are proportional to at least one factor of x dot,
  • 00:29:45
    y dot, or z dot, so they all vanish as well.
  • 00:29:48
    Let me draw a picture of these world lines.
  • 00:29:51
    So here's the t axis --
  • 00:29:53
    [ Typing ]
  • 00:29:58
    -- y axis, and the z axis.
  • 00:30:03
    Try to suppress the x axis.
  • 00:30:05
    Each of these world lines is at a constant value of x, y, z,
  • 00:30:08
    and just runs parallel to the t axis.
  • 00:30:16
    So this is the family of geodesics.
  • 00:30:18
    Each one of these geodesics has a four velocity x dot mu, which is 1, zero, zero, zero.
  • 00:30:28
    This might seem like a strange result, after all they're supposed
  • 00:30:31
    to be a gravitational wave propagating through space along the z direction.
  • 00:30:36
    [ Typing ]
  • 00:30:45
    Yet these particles don't seem to be influenced by the wave; they're just staying still
  • 00:30:49
    at the same location, x naught, y naught, z naught, as time passes.
  • 00:30:54
    The key to understanding what's happening is to recognize that as the gravitational wave passes,
  • 00:30:59
    the particles remain at rest in this coordinate system.
  • 00:31:03
    [ Typing ]
  • 00:31:19
    The emphasis here is on this coordinate system.
  • 00:31:22
    [ Typing ]
  • 00:31:27
    So when we say that the particles remain at rest,
  • 00:31:30
    that statement has no intrinsic geometrical or physical meaning, it's a statement that depends
  • 00:31:36
    on the coordinate system that we've chosen.
  • 00:31:38
    So what we'd really like to do is compute a proper separation between two
  • 00:31:42
    of these particles, say between this world line and this world line,
  • 00:31:46
    and monitor that separation in time.
  • 00:31:49
    But how would we do that?
  • 00:31:50
    For example, we can pick an event on this world line, and another event on this world line,
  • 00:31:55
    and then choose a path between those events and compute that proper distance.
  • 00:32:01
    But what if we chose a different point on this world line or a different path?
  • 00:32:06
    So you can see from here that this notion of the proper distance
  • 00:32:10
    between world lines is ambiguous.
  • 00:32:12
    [ Typing ]
  • 00:32:23
    It's not well defined --
  • 00:32:24
    [ Typing ]
  • 00:32:29
    -- unless we do something to specify which points and paths we're taking.
  • 00:32:33
    So it's ambiguous without Further input for choosing the paths and points.
  • 00:32:45
    [ Typing ]
  • 00:32:51
    Points or events on the world lines.
  • 00:32:55
    I think the best way to supply this further input is to ask, what would an observer see?
  • 00:33:02
    An observer who's riding along one of these geodesics,
  • 00:33:05
    what would they see happening to the particles nearby?
  • 00:33:08
    So to answer that question we'll choose an observer who's riding right along the t axis --
  • 00:33:13
    [ Typing ]
  • 00:33:20
    -- and construct fermi normal coordinates in the neighborhood, this observer,
  • 00:33:23
    and use the fermi normal coordinates to track the motion of the nearby particles.
  • 00:33:30
    So we'll choose our observer --
  • 00:33:32
    [ Typing ]
  • 00:33:37
    -- at x equal y equals z equals zero.
  • 00:33:41
    This is one of the geodesics we computed before.
  • 00:33:44
    [ Typing ]
  • 00:33:47
    And then we'll construct fermi normal coordinates for this observer.
  • 00:33:51
    [ Typing ]
  • 00:34:05
    I discussed fermi normal coordinates in detail in Lecture 10.
  • 00:34:08
    So see Lecture 10.
  • 00:34:11
    [ Typing ]
  • 00:34:14
    And there I used a bar to denote the coordinates.
  • 00:34:17
    [ Typing ]
  • 00:34:20
    So the fermi normal coordinates were called x bar mu, and they're often used
  • 00:34:25
    for x bar zero, I'll often use Tao.
  • 00:34:29
    So Tao is also x bar zero tabbing proper time along the observers' world line.
  • 00:34:36
    And then the spatial coordinates were just to know x bar a,
  • 00:34:40
    where a ranges over one, two and three.
  • 00:34:44
    The key result that I showed in this lecture 10, was that the components
  • 00:34:48
    of the metric in fermi normal coordinates --
  • 00:34:50
    [ Typing ]
  • 00:34:59
    -- call that g mu nu bar, the components of the metric
  • 00:35:03
    in those coordinates are just ADA mu nu plus terms that are quadratic
  • 00:35:08
    and higher order in the x bar a's.
  • 00:35:10
    [ Typing ]
  • 00:35:21
    This result tells us that close to the world lines of the observer,
  • 00:35:25
    let's call the observer o, so close to o's world line.
  • 00:35:32
    [ Typing ]
  • 00:35:35
    In other words, where x a bar is small, and we can ignore these quadratic terms,
  • 00:35:44
    then the observer o can use special relativity.
  • 00:35:47
    [ Typing ]
  • 00:35:55
    They can use everything they know about special relativity to interpret all
  • 00:35:58
    of the results and all of the physics.
  • 00:36:00
    And in particular, x bar as' are just spatial Cartesian coordinates.
  • 00:36:07
    [ Typing ]
  • 00:36:14
    And x bar zero of course is Tao is just proper time for the observer.
  • 00:36:21
    [ Typing ]
  • 00:36:28
    Now let's recall how fermi normal coordinates are constructed.
  • 00:36:32
    And just for notational simplicity and consistency,
  • 00:36:35
    I think I'll denote the x bar zero coordinate,
  • 00:36:38
    the proper time along the observers world line is t bar.
  • 00:36:42
    So the fermi normal coordinates will be t bar and x bar a, and sometimes I'll use x bar,
  • 00:36:48
    y bar, z bar, for these spatial fermi normal coordinates.
  • 00:36:52
    So here's the observers world line, the observer's o, and the worldwide is defined
  • 00:36:58
    in terms of our original spacetime coordinates as x mu as a function
  • 00:37:03
    of proper time along the world line.
  • 00:37:05
    Proper time I'll denote by tab -- t bar.
  • 00:37:08
    And just to remind ourselves that this is the observer's world line,
  • 00:37:12
    I'll put a little subscript script o here for observer.
  • 00:37:16
    So the four velocity of the observer is u sub o equals u sub o dot.
  • 00:37:24
    The observer constructs fermi normal coordinates by first picking a time,
  • 00:37:29
    let's say t bar equals zero, and here's the four velocity at that time.
  • 00:37:38
    The observer then chooses three spatial basis vectors, e1, e2, and e3,
  • 00:37:42
    such that these basis vectors are orthogonal to the four velocity u
  • 00:37:54
    and also orthogonal to each other and normalized.
  • 00:37:58
    So if we refer to these three basis factors collectively as e sub a, and we have e sub a
  • 00:38:04
    as orthogonal to the observers world line, and also these are orthonormal.
  • 00:38:10
    So ea dot eb is delta ab.
  • 00:38:14
    And now the observer defines basis vectors all along the world line
  • 00:38:21
    by parallel transporting these basis vectors.
  • 00:38:24
    [ Typing ]
  • 00:38:27
    So define the ea's along the world line --
  • 00:38:30
    [ Typing ]
  • 00:38:36
    -- by parallel transport.
  • 00:38:37
    [ Typing ]
  • 00:38:43
    So that's mu alpha dell alpha e mu a equals zero.
  • 00:38:49
    As I showed back in Lecture 10, if these orthogonality conditions hold
  • 00:38:53
    at the initial time at t bar equals zero, then they'll continue to hold into the future,
  • 00:38:59
    as these basis vectors are parallel transported.
  • 00:39:02
    Physically, the way the observer defines these basis vectors is with a set of gyroscopes.
  • 00:39:08
    The access to the gyroscope defines a spatial direction,
  • 00:39:12
    and that direction is parallel transported into the future as long
  • 00:39:15
    as there are no torques acting on the gyroscope.
  • 00:39:22
    The main result of this construction is a coordinate transformation
  • 00:39:25
    between the original spacetime coordinates and the fermi normal coordinates.
  • 00:39:29
    [ Typing ]
  • 00:39:37
    So the original coordinates x mu has functions
  • 00:39:41
    of the fermi normal coordinates t bar x bar a were forgiven by x mu of o's worldwide
  • 00:39:50
    and that's function of t bar plus the basis vector ea mu.
  • 00:39:56
    And that's a function of t bar, since the base vectors have been parallel transported along the
  • 00:40:01
    world line, times x bar a minus 1/2 the Christoffel symbols, gamma mu alpha beta.
  • 00:40:09
    And these are evaluated along the world lines so there are functions of t bar times e alpha a,
  • 00:40:16
    which is a function of t bar times e beta b, which is function t bar times x a bar x b bar.
  • 00:40:26
    And then there are higher order terms in the x bar a's.
  • 00:40:31
    Now let's transform our gravitational wave metric into fermi normal coordinates.
  • 00:40:35
    [ Typing ]
  • 00:40:42
    So remember the metric has the form of the flat spacetime metric,
  • 00:40:46
    and Minkowski coordinates plus a small perturbation.
  • 00:40:50
    And the only nonzero components of the perturbation are the xx and yy components.
  • 00:40:55
    And those are equal to plus or minus a times sine of Omega t minus z. So if we put
  • 00:41:00
    that together the metric is diagonal.
  • 00:41:03
    So let me write it this way, diagonal minus 1, then 1 plus a sine
  • 00:41:11
    of Omega t minus z. The next entry, the yy entry is 1 minus a times sine of Omega t minus t.
  • 00:41:25
    And the zz component is just plus 1.
  • 00:41:27
    And remember this amplitude a's small.
  • 00:41:31
    Now our observer o just sits at x equal y equals z equals zero
  • 00:41:37
    at the origin and these coordinates.
  • 00:41:41
    And so the world line of the observer x mu sub o is a function
  • 00:41:47
    of t bar is just t bar, zero, zero, zero.
  • 00:41:54
    So the four velocity of the observer is just 1, zero, zero, zero.
  • 00:42:02
    And now we need to construct these basis vectors, the ea mu.
  • 00:42:05
    Because the metric is diagonal, it's pretty easy to guess.
  • 00:42:10
    We'll take e1 mu to be zero, 1 divided by the square root of 1 plus a sine Omega t minus z --
  • 00:42:24
    [ Typing ]
  • 00:42:27
    -- zero, zero, e2 mu is zero, zero, 1 divided by the square root
  • 00:42:35
    of 1 minus a sine Omega t minus c, zero, and e3 mu is equal to zero zero zero 1.
  • 00:42:50
    Now because the metric is diagonal, you can tell just by inspection that each
  • 00:42:54
    of these vectors is orthogonal to u, and they're also orthogonal
  • 00:42:59
    to each other, and they're also normalized.
  • 00:43:02
    But let's remember, we're constructing a set of basis vectors along the world line where x, y,
  • 00:43:08
    and z are equal to zero and t is equal to t bar.
  • 00:43:12
    So for the basis of vectors on the world line, we can replace this combination t minus z
  • 00:43:18
    with t bar, and this t minus z is t bar.
  • 00:43:25
    Let's also remember that this parameter a is very small and we're carrying out all
  • 00:43:29
    of our calculations just to linear order in a. So let's write these basis vectors
  • 00:43:35
    to linear order in a, e mu 1 is zero, 1 minus a over 2 times sine of Omega t bar, zero, zero,
  • 00:43:49
    e mu 2 zero, zero, 1 plus a over 2 times sine of Omega t bar,
  • 00:43:58
    zero, and e mu 3 is zero zero zero 1.
  • 00:44:04
    Now there's one more condition that we need to check.
  • 00:44:07
    We need to know that these basis vectors are parallel transported along the world line.
  • 00:44:12
    [ Typing ]
  • 00:44:28
    So it's possible to have a set of basis vectors that are orthogonal and normalized
  • 00:44:32
    in space like, they're space like in respect to the world line, but they rotate relative
  • 00:44:37
    to the basis vectors that are parallel transported.
  • 00:44:41
    In other words, they rotate relative to the directions defined by the inertial gyroscopes.
  • 00:44:46
    So we need to know that our set of basis vectors is not rotating.
  • 00:44:51
    So we need to check that u alpha del alpha e mu a is equal to zero.
  • 00:45:01
    Now this can be expanded in terms of ordinary derivatives and Christoffel symbols
  • 00:45:05
    to give e mu a dot, the dot is differentiation with respect
  • 00:45:09
    to proper time t bar plus gamma mu alpha beta e alpha a u beta.
  • 00:45:17
    But u beta is just 1 zero zero zero.
  • 00:45:19
    So this is e mu a dot plus gamma mu alpha zero e alpha a.
  • 00:45:27
    So let's first consider this basis vector.
  • 00:45:30
    Let's let a equal 1 so we can immediately compute e1 dot is zero,
  • 00:45:38
    the derivative of this is minus a over 2 times Omega times cosine
  • 00:45:45
    of Omega times t bar, zero, zero.
  • 00:45:49
    That takes care of this term, now let's compute this term.
  • 00:45:52
    We have gamma nu alpha zero e alpha a. Knowing the sum over alpha,
  • 00:46:00
    the only nonzero term is when alpha is equal to 1.
  • 00:46:03
    So what this is gamma nu 1 zero times 1 minus a over 2 sine of Omega t bar.
  • 00:46:12
    So we need to compute these Christoffel symbols.
  • 00:46:15
    [ Typing ]
  • 00:46:18
    We have gamma mu 1 zero is 1/2 g mu times partial 1 g zero nu plus partial zero g 1 nu
  • 00:46:29
    minus partial nu g 1 zero.
  • 00:46:32
    Now remember the metric is diagonal, so this term is equal to zero.
  • 00:46:36
    And also the only nonzero term here is when nu is equal
  • 00:46:40
    to zero but g zero zero is just minus 1.
  • 00:46:43
    So the derivative of minus 1 is zero.
  • 00:46:46
    And now the only nonzero term here in the sum over nu is when nu is equal to 1.
  • 00:46:51
    So this is equal to 1/2 g mu 1 times the derivative of g 1 1,
  • 00:46:58
    but g 1 1 is just 1 plus a sine of Omega t minus z.
  • 00:47:06
    [ Typing ]
  • 00:47:09
    So this simplifies to 1/2 g mu 1 times a Omega cosine Omega t minus z. Now let's remember,
  • 00:47:21
    we're evaluating this along the world line where z is equal to zero and t is equal to t bar.
  • 00:47:28
    So gamma mu 1 zero on the world line is equal to 1/2 g mu 1 times a Omega cosine of Omega t bar.
  • 00:47:40
    And now we can insert this result in here, and this index a should actually be a 1.
  • 00:47:48
    And then gamma mu alpha zero e alpha 1 is equal to 1/2 g mu 1 times a Omega cosine
  • 00:48:00
    of Omega t bar times this factor 1 minus a over 2 times sine of Omega t bar.
  • 00:48:10
    Now let's remember that we're carrying out all of our calculations to linear order
  • 00:48:14
    in this small amplitude a. And we already have in fact, a here.
  • 00:48:18
    So this term can be dropped because it just contributes quadratic terms to our answer.
  • 00:48:24
    And also g mu nu, to leading orders, is just a flattened Cartesian metric a mu nu.
  • 00:48:29
    So this is approximately 1/2 ADA mu 1 a Omega cosine of Omega t bar
  • 00:48:37
    to linear order in the small parameter --
  • 00:48:41
    [ Typing ]
  • 00:48:44
    -- a.
  • 00:48:45
    [ Typing ]
  • 00:48:49
    Now of course, ADA mu 1 is only nonzero when mu is equal to 1.
  • 00:48:53
    So let's write our answer this way, zero, 1/2 a Omega cosine Omega t bar, zero, zero.
  • 00:49:03
    Now we can compare this result to our previous result for e1 dot,
  • 00:49:10
    and we see that they're just the same but with opposite signs.
  • 00:49:14
    So the sum of these two terms equals zero.
  • 00:49:17
    So what we've just shown is that for the basis factor e1,
  • 00:49:21
    it's parallel transported along the world line.
  • 00:49:24
    And by similar calculation, you can show that e2 and e3 are also parallel transported.
  • 00:49:30
    So we've now confirmed that the basis vectors are parallel transported along the world line.
  • 00:49:35
    So the ea's are parallel transported.
  • 00:49:42
    [ Typing ]
  • 00:49:45
    They satisfy u alpha del alpha e mu a equals zero.
  • 00:49:52
    Now we can put all of this together to construct the coordinate transformation
  • 00:49:56
    from our original spacetime coordinates to fairly normal coordinates.
  • 00:50:02
    So here are the basis vectors that we need --
  • 00:50:12
    -- and this is the coordinate transformation.
  • 00:50:20
    This transformation is expressed in terms of the series expansion
  • 00:50:23
    in the spatial Fermi normal coordinates, the x bar a's, and for present purposes,
  • 00:50:29
    we only need this expansion out to linear order,
  • 00:50:31
    the x bar a. So we only need this part of the expression.
  • 00:50:35
    So explicitly this coordinate transformation is given by the following.
  • 00:50:41
    [ Typing ]
  • 00:50:51
    We have t equals t bar, x equals 1 minus 1/2a times sine of Omega t bar times x bar,
  • 00:51:07
    y equals 1 plus 1/2a sine of Omega t bar times y bar, and z equals z bar.
  • 00:51:18
    And I'll remind you that there are higher order terms in the spatial fermi normal coordinates.
  • 00:51:23
    So this is accurate through linear order --
  • 00:51:25
    [ Typing ]
  • 00:51:32
    -- in the x bar a's.
  • 00:51:35
    And as always, it's accurate through linear order --
  • 00:51:37
    [ Typing ]
  • 00:51:42
    -- in small amplitude a. Now let's invert these relations.
  • 00:51:51
    You have t bar equals t, and x bar equals the inverse of this factor to linear order a,
  • 00:51:59
    is just 1 plus 1/2a times sine of Omega times t bar, but t bar is equal to t plus corrections,
  • 00:52:10
    but this is already a small term because of the factor of a so we can just replace t bar
  • 00:52:14
    with t here, then times x. And likewise y bar is equal to 1 minus 1/2a time sine
  • 00:52:23
    of Omega t times y, and z bar equals z. Now recall from earlier in the lecture,
  • 00:52:34
    we found a family of geodesics --
  • 00:52:39
    [ Typing ]
  • 00:52:44
    -- which were given by x equals a constant x naught, y equals a constant y naught,
  • 00:52:51
    z equals a constant z naught, and t just equals the proper time along the geodesic Tao.
  • 00:52:58
    Using this coordinate transformation, we can write down these world lines, these geodesics,
  • 00:53:03
    in terms of fermi normal coordinates.
  • 00:53:05
    You have t bar equals Tao, x bar equals 1 plus a over 2 times sine of Omega Tao times x naught,
  • 00:53:20
    y bar equals 1 minus a over 2 times sine of Omega Tao times y naught, z bar equals z naught.
  • 00:53:32
    Keep in mind that the observer who's sitting at the origin can interpret these coordinates
  • 00:53:37
    to spacial coordinates x bar, y bar, and z bar as Cartesian coordinates.
  • 00:53:42
    [ Typing ]
  • 00:53:49
    So the values of these coordinates give the actual proper distances along orthogonal spatial
  • 00:53:54
    directions, and at the same time is defined by the observer.
  • 00:53:58
    So what the observer sees is that any particles that are displaced from your origin
  • 00:54:02
    in the x bar y bar plane, will undergo oscillations with angular frequency Omega.
  • 00:54:08
    However, notice that the oscillations in the x bar and y bar directions are out of phase
  • 00:54:13
    by 180 degrees due to the sine difference.
  • 00:54:17
    So for example, let's take a look in the x bar y bar plane.
  • 00:54:27
    So this is the x bar axis, this is the y bar axis.
  • 00:54:32
    Now here's a test particle on the x bar axis at Tao equals zero,
  • 00:54:37
    so it's at location x bar equals x naught.
  • 00:54:41
    Now as Tao increases the bar code moves outward.
  • 00:54:47
    So after a fourth of the period, it moved to location 1 plus a over 2 times x naught.
  • 00:54:52
    And similarly, if we have a particle on the y axis during the first 1/4 of a period,
  • 00:54:58
    it will move towards the origin by an amount minus a over 2 times y naught.
  • 00:55:05
    We can in fact consider a whole ring of test particles.
  • 00:55:10
    So initially these particles are spread out in a circle and during the first 1/4 of the period,
  • 00:55:17
    this particle will move outward, find them out, they over 2 times x naught.
  • 00:55:23
    This particle will move inward.
  • 00:55:25
    So the whole pattern, the whole ring distorts into a ellipse.
  • 00:55:34
    So this is the ring at Tao equals zero, and this is the ring at Tao equals pi
  • 00:55:43
    over 2 Omega, which is 1/4 of the period.
  • 00:55:47
    Then after another 1/4 of a period, the ring returns to its original shape.
  • 00:55:53
    So this is also the shape at Tao equals pi over Omega after half a period.
  • 00:55:59
    Then during the next fourth of a period,
  • 00:56:01
    these particles all shift in the opposite directions --
  • 00:56:04
    [ Typing ]
  • 00:56:07
    -- so the ring distorts into an ellipse that's elongated in the y bar direction.
  • 00:56:17
    So this is the ring at Tao equals 3 pi over 2 Omega.
  • 00:56:23
    And finally, after a full period, 2 pi over Omega, the ring returns to the original shape.
  • 00:56:31
    So this picture shows the physical measurable effect that a gravitational wave has on a set
  • 00:56:36
    of freely falling on accelerated test masses.
  • 00:56:40
    So these are freely falling and therefore are accelerating --
  • 00:56:45
    [ Typing ]
  • 00:56:49
    -- test masses.
  • 00:56:51
    [ Typing ]
  • 00:56:56
    Let me summarize.
  • 00:56:59
    What I've shown is an example of the gravitational wave.
  • 00:57:02
    [ Typing ]
  • 00:57:11
    And it was defined by the metric probation h mu nu which was diagonal zero a sine
  • 00:57:20
    of Omega t minus z, a minus a sine of Omega t minus z, zero.
  • 00:57:32
    And this is a plane wave propagating in the z direction --
  • 00:57:39
    [ Typing ]
  • 00:57:49
    -- and with what is called the plus polarization.
  • 00:57:53
    [ Typing ]
  • 00:58:02
    The term plus for the polarization comes from the effect that it has on a ring of test masses.
  • 00:58:07
    They distort into a sort of plus pattern.
  • 00:58:11
    And another thing that you should notice from this example,
  • 00:58:13
    that's true of all gravitational waves, is that the wave is transverse.
  • 00:58:19
    [ Typing ]
  • 00:58:25
    In other words, the wave only affects the separation between test masses
  • 00:58:29
    in the plane that's transverse to the direction of propagation.
  • 00:58:33
    In the next lecture, we'll show how this example is derived and also show
  • 00:58:38
    that there's another polarization state called cross polarization.
  • 00:58:42
    So next lecture --
  • 00:58:44
    [ Typing ]
  • 00:58:48
    -- we'll derive the plus and the cross polarization gravitational waves.
  • 00:58:57
    [ Typing ]
标签
  • gravitational waves
  • LIGO
  • neutron stars
  • black holes
  • VIRGO
  • LISA mission
  • KAGRA
  • Einstein equations
  • Fermi normal coordinates
  • gauge freedom