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Technology

New Atomic Clock Reaches the Boundaries of Timekeeping 249

SonicSpike sends an article from NPR about a high-tech clock being built at the University of Colorado Boulder. It's more precise than any clock before, able to keep perfect time for five billion years. "At the heart of this new clock is the element strontium. Inside a small chamber, the strontium atoms are suspended in a lattice of crisscrossing laser beams. Researchers then give them a little ping, like ringing a bell. The strontium vibrates at an incredibly fast frequency. It's a natural atomic metronome ticking out teeny, teeny fractions of a second." But this precision leads to a problem: the relativistic differences between keeping the clock on the floor versus hanging it on the wall now introduce more significant fluctuations than the clock itself. "Tiny shifts in the earth's crust can throw it off, even when it's sitting still. Even if two of them are synchronized, their different rates of ticking mean they will soon be out of synch. They will never agree. The world's current time is coordinated between atomic clocks all over the planet. But that can't happen with the new one."
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New Atomic Clock Reaches the Boundaries of Timekeeping

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  • Old saying (Score:5, Insightful)

    by plover ( 150551 ) on Monday November 03, 2014 @07:34PM (#48306109) Homepage Journal

    A man with one watch always knows what time it is.
    A man with two watches is never sure.

    • by SJHillman ( 1966756 ) on Monday November 03, 2014 @07:44PM (#48306171)

      A man with an atomic watch won't shut up about it.

    • Re:Old saying (Score:5, Interesting)

      by Anonymous Coward on Monday November 03, 2014 @07:55PM (#48306233)

      Another old saying I like, from sailors:

      When going to sea, take one clock or three, but never two.

      (Knowing the time was essential for navigation, to figure out longitude, back in the days before GPS navigation.)

    • Re:Old saying (Score:5, Insightful)

      by lgw ( 121541 ) on Monday November 03, 2014 @08:29PM (#48306419) Journal

      A further problem with hyper-accurate clocks is relativity. TFS mentions the issues with general relativity - strength of gravity affects timekeeping. But there's a more profound issue once you get crazy-precise: only co-moving clocks can be synchronized in the first place. The concept of synchronization simply doesn't apply to clocks moving at different velocities - and two clocks at different positions on the rotating, orbiting Earth will never quite be moving with the same velocity. That relativistic effect is tiny, but it's not even hypothetically reconcilable: there are only so many significant digits of time possible to share between clocks in different locations.

      • Why can't we compute what the relativistic slew rate between two different locations will be and compensate?
        • Re: Old saying (Score:5, Interesting)

          by mpoulton ( 689851 ) on Monday November 03, 2014 @09:50PM (#48306777)
          Because it would be meaningless to "compensate" for the time difference between clocks moving and accelerating differently. Time literally moves at different rates in different reference frames. The clocks are correct; the problem is that the concept of similtaneity is fundamentally flawed.
          • Only on that level. For most everything else, it's fine. So not so much "fundamentally", you just need to apply it appropriately, much like Newtonian physics. You don't need to factor in QM to build a plane.

          • Because it would be meaningless to "compensate" for the time difference between clocks moving and accelerating differently.

            It isn't "meaningless", it's just not very useful.

            The real problem is that with "clocks" this precise, there must be an acceleration standard in addition to the other standards.

            I suggest that 3 be placed on the same fixed level surface, at some kind of "elevation" standard based on effective gravity, so that tectonic changes. Because this is an obvious source of potential error. Just for one example, a recent media article was all about "sea level rise" on the East U.S. coast, when in fact most if not

            • s/so that tectonic changes/so that tectonic changes are accounted for
            • by Hadlock ( 143607 )

              As of about 2010 we already had clocks so accurate you could demonstrate relativistic effects by separating them by just a few feet. It sounds like the vibration from walking in the same room as these is enough to knock them out of sync.

          • ...the problem is that the concept of similtaneity is fundamentally flawed.

            I don't think so. When it comes to physics, I'm an informed layman at best, but I don't think that the concept itself is flawed. The flaw comes in when people try to apply it in a situation where it just doesn't apply. As an example, it certainly doesn't apply at astronomical distances; we can't know exactly where Alpha Centauri is and what's happening there right this minute; we can only know what was going on 4.366 years ago.
          • Because it would be meaningless to "compensate" for the time difference between clocks moving and accelerating differently. Time literally moves at different rates in different reference frames. The clocks are correct; the problem is that the concept of similtaneity is fundamentally flawed.

            I'll admit, I don't understand why the arbitrary reference time we use currently is any less valuable now that we have surface clocks whose real time is measurably changing due to relativistic effects.

          • I think it is wrong to say simultaneity is wrong. The fact that the two clocks are correct does not mean simultaneity does not exist, it only means that we cannot measure simultaneity with clocks.

            The fact is thinga happen in parallel in the universe, and so simultaneity exists, because for any event another event would have to have happened at the same time.

            • by lgw ( 121541 )

              Simultaneity doesn't mean what you want it to mean. There's no arbitrary universal time in which things can be said to happen simultaneously. Even the order of events can be different depending on the frame of reference of the observer (but causality is always protected). You can pick an arbitrary frame, of course, but you can only observe distant events after the speed-of-light delay, which itself depends on relative velocity. Since we're constantly accelerating, even that comes down to arbitrary choice

            • You're problem is thinking of time as absolute. "Now" travels at the speed of light, so depending on your frame of reference and distance from the event, your "now" would be different to someone travelling at a different velocity and it's quite possible that you'd disagree about the order of events happening.

              In the larger universe, it's more obvious that there is no single frame of reference to which you can pin "simultaneity". "Same time" only makes sense in a single frame of refernce.
        • Because you'd have to do it in realtime, or whatever passes for it when dealing with relativistic effects on this scale. Otherwise, microscopic shifts in the Earth's crust will soon change the slew rate, and then you're back to square one. But calculating the slew rate will inevitably take longer than one tick of the clock, so you can't do it in realtime either.

          Though this property isn't entirely useless. For example, you could use two of these clocks to build extremely sensitive seismometers: first you wou

      • OK, but then time really is happening at different rates in the two different places. Would you want the clocks to show the same amount of time passing when it simply isn't? Should a second in China be minusculy shorter than one in America?
        • by lgw ( 121541 )

          In general relativity, you can paint a coherent picture. Both the observer deep in a gravity well and a distant observer agree that higher gravity makes clocks run slower. But that's not true of special relativity at all. Given two clocks moving relative to one another, each observer thinks the other's clock is running slower and they're equally right. There's simply no universal clock, no standard that's more right than any other clock.

        • Should a second in China be minusculy shorter than one in America?

          No. It should be slightly longer.

      • This is not a new problem, suddenly created by this clock. It already exists with our standard definition of time.

        So now we'll be averaging due to relativity differences as well as precision errors.

      • I actually addressed this just yesterday on Stack Exchange:
        http://astronomy.stackexchange... [stackexchange.com]

        Thanks!

    • Re: (Score:3, Interesting)

      Comment removed based on user account deletion
    • Old saying (Score:4, Funny)

      by rekoil ( 168689 ) on Monday November 03, 2014 @10:19PM (#48306895)

      That feeds into best practice for configuring NTP clients - configure one upstream source, or at least three. Never two.

      • Re:Old saying (Score:5, Informative)

        by WuphonsReach ( 684551 ) on Monday November 03, 2014 @11:16PM (#48307183)
        Best practice in the real world is four reference clocks or only one. With just three configured you run into the problem of ending up in the "just two clocks situation" more often then not. At which point, NTP is likely to oscillate between the two remaining good candidates (without the "prefer" keyword).

        How you choose to configure NTP is a tricky art depending on how resilient you want to be and whether you have a local time source or need less then 5ms accuracy. For most situations (99% of servers), being within 500ms of the "internet time" is enough. Your goal is mostly to avoid the issue where the clock is off by tens of seconds or worse.
    • Hey, I have a dozen watches (you insensitive clod) -- and I know how to calculate mean, median, and standard deviations!

      So there.

  • by unitron ( 5733 ) on Monday November 03, 2014 @07:52PM (#48306213) Homepage Journal

    ...that it can't be used to tell time reliably.

  • Problem... (Score:5, Funny)

    by Lab Rat Jason ( 2495638 ) on Monday November 03, 2014 @07:53PM (#48306221)

    That sounds like a 0th world problem...

  • able to keep perfect time for five billion years

    • by Pope Hagbard ( 3897945 ) on Monday November 03, 2014 @08:03PM (#48306273) Journal

      Not warranted for war, plagues, pestilence, or the power going out for an extended period.

    • by PolygamousRanchKid ( 1290638 ) on Monday November 03, 2014 @08:08PM (#48306311)

      Yes, but you probably need to change the battery every few million years or so. That's where they will make their money . . . kinda sorta like printer cartridges or iPhone batteries.

      You get the atomic clock cheap, but those extras cost you!

      • But for one simple payment or $100,000, you can pre-purchase your batteries for the next 500 billion years!

    • It can't keep 'perfect time' for any length of time at all. Perfect means zero error. This might be an astoundingly accurate clock but that does not make it perfect.
      • It can't keep 'perfect time' for any length of time at all. Perfect means zero error. This might be an astoundingly accurate clock but that does not make it perfect.

        Time is relative to the imperfect Universe in which it and the clock exist.

      • by Bengie ( 1121981 ) on Monday November 03, 2014 @10:40PM (#48307003)
        Since "perfect" is impossible, making it a useless word, lets just redefine it to something useful, like the colloquial usage of "close enough with respect to the current standard margin of error.
        • by Trogre ( 513942 )

          Dammit where are my mod points? You just shot down a whole lot of pedants with that comment.

        • A mathematician and an engineer are sitting at a table drinking when a very beautiful woman walks in and sits down at the bar.

          The mathematician sighs. "I'd like to talk to her, but first I have to cover half the distance between where we are and where she is, then half of the distance that remains, then half of that distance, and so on. The series is infinite. There'll always be some finite distance between us."

          The engineer gets up and starts walking. "Ah, well, I figure I can get close enough for all pract

        • ...with respect to the current standard margin of error

          ...and there is your problem. The margin of error depends on what you are doing hence your redefinition of 'perfect' is utterly useless since you need to specify your margin of error...in which case you might as well just skip calling it perfect. Despite you assertion to the contrary even though perfect is not obtainable it is still a useful concept to compare reality against e.g. this clock is closer to perfect time keeping than its predecessors.

      • by JigJag ( 2046772 )

        "Perfect means zero error"

        Years ago, I used to think like you, but now I disagree with this statement. For me, perfect means meeting the requirements. Zero error is a requirement but not a reasonable one. My life got much more pleasant when I realized I should aim for meeting reasonable requirements instead of an elusive zero error target.

  • "...able to keep perfect time for five billion years."

    If they were able to create a device that could actually keep the time for five billion years, perfect or not, I would be pretty damn impressed.

    • "...able to keep perfect time for five billion years."

      If they were able to create a device that could actually keep the time for five billion years, perfect or not, I would be pretty damn impressed.

      My first thought as well, would take a hell of a Radioisotope to generate power for that long.
      Wars and such would disrupt it's power after some time if not on an independent power supply.

      But in the end due to the relativistic differences (Earth quakes and such); of anyone looking at the clock for the time it was started or past would make it useless - unless you did the math.

  • Misleading Title (Score:4, Interesting)

    by arobatino ( 46791 ) on Monday November 03, 2014 @08:14PM (#48306357)

    New Atomic Clock Reaches the Boundaries of Timekeeping

    On Earth, maybe. It's not a theoretical limit - the article itself points out that you can put the clocks in space.

    Ye suspects the only way we will be able to keep time in the future is to send these new clocks into space. Far from the earth's surface, the clocks would be better able to stay in synch, and perhaps our unified sense of time could be preserved.

    • Space is about the only place such clocks would be of any use. I could see them being used to provide GPS like localization services for any craft designed to leave earth's orbit. For it to work you require synchronized clocks. But, unlike GPS, there is no way to perform such a synchronization. You end up having to rely on the accuracy of the two clocks.
    • Yeah, but, ... if the clocks have to be up in space to be fully accurate, etc., What is the meaning of the word "today" in the sentence "You will not go to space today" ?
      [joke, dammit!!!]

  • Would they actually be able to detect the change in the flow of the time with just one clock, or would they need to have a reference clock somewhere and measure another clock relative to it? And if so, where do you keep the reference? Where in the universe is it the "correct" time?
    • by Altrag ( 195300 )

      Where in the universe is it the "correct" time?

      Wherever you decide it should be. The universe doesn't have any special reference frame so you just make one up. Similar to how somebody just arbitrarily picked a line of longitude to be GMT+0 back when they were figuring out time zones.

  • ..This looks to be a pretty complicated beast that's built onto a table top and looks very much like a graduate research lab.. I wonder what the up time is?.. Mounts can drift with temperature, the bench does not look sealed, there is the potential for dust and contamination.. The laser power can fluctuate every so slightly and are probably run in optical-power mode.. The lasers can't be constantly up, etc. ..I used to work at a laser company that converted a bench-top tunable femtosecond laser with a lot o
  • It's reality that is frequently inaccurate.
  • Right now, atomic clocks use cesium. Why is strontium better?
  • How do you originally set the clock? If this is the first time you will have such an accurate measurement of time, then how do you know what time it is so you can set the clock?
  • by rossdee ( 243626 )

    They still have to change it every 6 months to account for daylight saving or the reverse.

  • The world's current time is coordinated between atomic clocks all over the planet. But that can't happen with the new one.

    However precise the clock is, we can still use it to coordinate time all over the earth. Just use the same number of significant digits we use today. Nobody is forcing you to consider ALL the available digits of precision.

  • Easy answer, build N+1 of them and use the 'average' value of time that they generate.

    One of my favourite quotes applies here:

    "When you have a clock you always know what time it is. When you have two you are never quite sure." - Mark Twain.

  • Gravity (Score:4, Interesting)

    by Triklyn ( 2455072 ) on Tuesday November 04, 2014 @09:37AM (#48309437)

    I find immense beauty in the fact that they set out to make as perfect a tracker of time they could. And end up creating an improved gravity detector when they ran into a wall. :) tell me again, that basic science doesn't deserve funds.

  • The Doctor should be arriving any time, so to speak.

"Hello again, Peabody here..." -- Mister Peabody

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