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Einstein's Theory To Go Beta Testing

Posted by timothy on from the relawhatnow dept.

pinqkandi writes: "This article over at CNN looks into the relativity of Einstein's theory of relativity (pun intended) as equipment becomes more and more precise. Soon atomic clocks will be placed in the International Space Station to analyze the accuracy of Einstein's theories. One of the lead researchers says that if Einstein's theory is not right, it will only need minor adjustments to account for changes in space-time, due to its deadly accurate precision."

8 of 326 comments (clear)

  1. Kostelecky's page... by doru · · Score: 5, Informative

    is here, with a little more information on Lorentz and CPT violation.

  2. GPS Satelites know this ! by fisman · · Score: 5, Informative

    AFAIK the current GPS satelite system makek adjustments for relativity in the signals it is sending around and they have been adjusting for this for years. See the articles at Metaresearch and lsu.edu for more info.

  3. In other news today... by meringuoid · · Score: 5, Funny

    Soon accurate telescopes will be installed to make extremely careful measurements of Mercury's orbit to analyze the accuracy of Newton's theories. One of the lead researchers says that if Newton's theory is not right, it will only need minor adjustments, due to its deadly accurate precision.

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  4. So sad by NiftyNews · · Score: 5, Funny

    Too bad Einstein isn't around anymore...

    He would have made for one heck of a great match on Fox Celebrity Boxing 3 with Stephen Hawking.

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  5. Re:What's wrong with the older proofs? by DarkState · · Score: 5, Informative

    The tests that Kostelecky is proposing are somewhat different than the earlier tests. In the previous tests researchers looked for changes in the frequency difference between two clocks when they were moving at different velocities or when they were at different heights in the earth's gravitational field. These tests looked at standard relativity theory (either special or general) and checked that the predictions it made were correct. In the new tests, one looks for changes in the frequency of a clock as it points in different directions (which would be akin to an ether, picking out a prefered direction in space) or a similar effect as the velocity of the clock changes.
    These tests have been performed on the ground recently by measuring the frequency of a clock as its direction relative to the stars changes due to the rotation of the earth. (For example, see Phillips, et al., Physical Review D 63, 111101 (2001) or Physical Review Letters 85, 5038 (2000)- showing off is always good.) In space, one could use the faster rotation of the space station as the atomic clocks in space which may substantially outperform ground based clocks.

  6. Re:Zero gravity? by delta407 · · Score: 5, Informative

    Technically, you're never going to get zero gravity. And yes, you're right, ISS isn't anywhere near that -- it's in orbit, and uses gravity to stay that way. ISS and the like are weightless (or near weightless) because they are effectually in a free fall; this state is termed "microgravity".

  7. Scientist Practical Jokes by DeadBugs · · Score: 5, Funny

    I wonder if Scientists ever play practical jokes on each other and sneak into the lab to make the Atomic Clock blink 12:00

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  8. Re:Relativity vs. Quantum Mechanics by Chuck+Lane · · Score: 5, Informative

    As coauthor of the Lorentz-violation paper being discussed, I'd like to reply to a few comments that have been made. This comment seems like a good starting point.

    _Special_ relativity and quantum mechanics have no trouble getting along. In fact, the so-called Standard Model of particle physics, based on relativistic quantum physics, is an enormously successful theory. The trouble lies in getting relativistic gravity (i.e., _general_ relativity) to play nice with quantum mechanics. This is where string theory comes in.

    The good thing about string theory is that it allows gravity and quantum mechanics to get along. The bad thing about string theory is that there is absolutely _no_ experimental evidence for it, and there are almost no possible tests of it that could be conducted in the near future. Lorentz violation is a major exception:
    The afore-mentioned Standard Model obeys a certain symmetry called ``Lorentz symmetry'', which lies at the heart of special relativity. However, string theory allows Lorentz symmetry to be broken. Thus, any experimental detection of Lorentz violation could be a great signature of string theory, and, maybe, quantum gravity. Moreover, there exist current experiments that are capable of detecting Lorentz violation to a very high precision.

    To summarize: We are studying Lorentz violation because (1) It is a possible signature of quantum gravity, and (2) It can presently be studied to very high precision.

    Chuck