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Science

Scientists Get Closer To Redefining the Length of a Second (npr.org) 100

Scientists are inching one step closer toward redefining the length of a second. NPR reports: Atomic clocks, which look like a jumble of lasers and wires, work by tapping into the natural oscillation of atoms, with each atom "ticking" at a different speed. The worldwide standard atomic clocks have for decades been based on cesium atoms -- which tick about 9 billion times per second. But newer atomic clocks based on other elements tick much faster -- meaning it's possible to divide a second into tinier and tinier slices. These newer atomic clocks are 100 times more accurate than the cesium clock. But it was important to compare them to each other -- to "make sure that a clock built here in Boulder is the same as a clock built in Paris, as in London, as in Tokyo," [Colin Kennedy, a physicist at the Boulder Atomic Clock Optical Network (BACON) Collaboration] says.

"Ultimately, the goal is to redefine the second in terms of a more accurate and precise standard, something that we can make more accurate and more precise measurements with," Kennedy says. As the scientists with BACON [...] wrote in the science journal Nature last week, they compared three next-generation atomic clocks that use different elements: aluminum, strontium and ytterbium. The scientists shot a laser beam through the air in efforts to connect their clocks, which are housed in two separate laboratories in Boulder, Colo. They also used an optical fiber cable. What resulted is a more accurate comparison of these types of atomic clocks than ever before. [N]etworks of clocks like this could also be used as super-sensitive sensors -- to possibly detect a passing wave of dark matter, and to test Einstein's theory of relativity.

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Scientists Get Closer To Redefining the Length of a Second

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  • How do they count the number of wave lengths to get the length of the speed of light ?
    • Paradoxically
    • Wild guess: Interference.
      In other words: With itself.

    • Re:How ? (Score:5, Informative)

      by tlhIngan ( 30335 ) <slashdot&worf,net> on Tuesday March 30, 2021 @03:47AM (#61216374)

      How do they count the number of wave lengths to get the length of the speed of light ?

      By counting.

      The atomic clock (really, an oscillator) works by a microwave emitter working at a certain frequency. That frequency is used to excite some atoms which if they are precisely the right frequency (remember, wavelength, frequency and energy are related), will cause electrons to jump from the ground energy state to an excited energy state.

      The magic is that inside the oscillator, it's possible to measure how many atoms are excited versus how many aren't. The frequency of the microwave emitter is then tweaked up or down slowly and the excited atom ratio re-evaluated. This repeats until the microwave emitter is "locked in" and the peak number of excited atoms is detected. At which point the output frequency of the microwave emitter is tapped and used as a reference frequency.

      The wavelength(frequency/energy) has to be tweaked so the most atoms will get excited, which requires an electron to jump from its ground energy state to an excited energy state. The energy has to be precise - too high a frequency (too much energy) and an electron cannot jump, too low, same thing. But just right, and the electron can make it to the next orbital shell.

      (This is because the energy levels are discrete from quantum mechanics. The element you use ha to be specially chosen to have really discrete energy levels as this will give the greatest "snap" - metals and semiconductors aren't good because in bulk they have wide energy bands making it hard to tune it precisely).

      Once you have the signal of known frequency, it's easy to divide it down from many GHz down to a much easier to use frequency.

      Remember, oscillator theory is basically a signal generator and a filter, and a loop gain over unity where the phase shifts more than 180 degrees. The microwave emitter is the signal generator, the atoms the filter. You can have poor filters using a resistor and capacitor, you get much better frequency stability using a quartz crystal because it only lets through a small band of frequencies, and the atomic excitation lets through an even narrower band of frequencies. Basically, the Q of atoms is off the charts.

      • Yes i understand they count, but im wondering how can you make something that counts something that happens that quickly. Again all that scaling and so on means well there might be rounding errors of some sort as the scaling happens.
        • by guruevi ( 827432 )

          You don't count 1 thing happening, you accumulate a number of these things happening. Kind of like charging a capacitor, after a while you can tell how much volt the circuit averages, but you're not adding up and counting individual peaks and valleys. Same with most atomic things, in quantum mechanics things happen randomly, you just average them out at various levels so you get a distribution of the most likely vs the least likely.

          We have systems that can oscillate and time very fast, so fast we can actual

          • Yes but we don't have anything this fast... which is the point. I understand his problem... at the end of the day you have an average of the rates of a group of atoms rather than confirmation each atom's pulse is in lockstep and actually at exactly the same rate. Then the issue of whether or not the thing you are measuring is actually a value out of phase with the reference. Including multi-reference much like you'd use multiple reference beams for a 3d hologram or to RGB/CMYK to colorize an image.

            I'm sure
            • by Agripa ( 139780 )

              Nothing at high frequency needs to be divided. A lower frequency can be multiplied and then the lower frequency divided, or there is nothing to prevent a mixer from operating at a high frequency and doing the phase comparison with a subharmonic directly, although it is not normally thought of that way.

        • Re:How ? (Score:4, Interesting)

          by SuricouRaven ( 1897204 ) on Tuesday March 30, 2021 @11:07AM (#61217452)

          It's not that fast - cesium clocks only run at a tad under 9.2GHz. Well within the frequencies commonly used for microwave communication.

    • Re: How ? (Score:2, Informative)

      by dbialac ( 320955 )
      Then there's the problem of what is a second in the first place. The earth's rotation slows down as the moon slowly gets closer and closer to it. A day in the 19th century was actually slightly shorter than it is today.
      • That is taken care of through the use of Leap Seconds.
      • by guruevi ( 827432 )

        Hence why they use measurements that are as independent from our environment as possible to figure out what a second is and then calibrate the rest around that.

      • A second is a fixed value. The speed of light is a fixed value, therefor the distance light travels in a second is fixed, therefor the value for a second is fixed. It isn't tied to the earth's rotation any longer.

        --
        • by dbialac ( 320955 )
          Sort of. There's units we need to use in our lives and units we need to use for science. They aren't always the same, and it's why a foot is a lot more convenient than a decimeter.
          • ... only for those who grew up using feet and have never had to learn another measurement system since. If your work life, daily life and scientific life all use different unit sets and you use them all every day, feet have no advantage over any other unit.

            I remember the utter confusion when I loaned a 100ft steel tape measure to a friend. (I'd pinched the tape from work.)

            • " 'Ere, this tape has only got 10 inches in a foot!"
            • "No it doesn't. It doesn't have any inch markings. It's marked in decimal feet - te
            • I can put one foot directly in front of another and get a good approximation of distance. I can do the same with a yard. The meter sort of works similar to the yard, but there's no equivalent to the foot.
      • OK, I checked [wikipedia.org]. The second moved from the Earth's rotation to Earth's orbit around the Sun in 1956 (as Suez was building up) and from the Earth's orbit into the atom in 1967. The successive definitions might not be comfortable or "homey", but they're not intended to be.

  • by gosso920 ( 6330142 ) on Tuesday March 30, 2021 @02:16AM (#61216226)
    Just use the "Mississippi" method to determine the length of a second.
  • by waynemcdougall ( 631415 ) <slashdot@codeworks.gen.nz> on Tuesday March 30, 2021 @02:18AM (#61216232) Homepage

    They're scientists.

    They're centimetering closer.

  • Quantum gas atomic clocks are considerably more precise than conventional atomic clocks. You'd have thought these would have been targeted.

    If not as a direct source, at the very least as a wholly independent means of measuring seconds, since the number of ticks they measure in this new second must be the same (allowing for gravity differences) in these different locations and the same number of ticks per the second versus these conventional atomic clock seconds.

    • Re:Sounds odd. (Score:4, Informative)

      by feedayeen ( 1322473 ) on Tuesday March 30, 2021 @04:01AM (#61216390)

      Going from the Nature paper itself rather than the journalist version in NPR. The intention of the experiment appears to be measuring the accuracy of a network of high precision clock sources for the purpose of other experiments like precise gravity detectors. This is why the facilities were separated by several kilometers and experimented with both open air and fiber based connections. That probably also explains why 3 different base elements were used, they want to perform the synchronization with different clock types.

  • But at that precision, the clocks in those places won't be the same. If only due to gravity variations along the planet's surface alone.

    • But at that precision, the clocks in those places won't be the same. If only due to gravity variations along the planet's surface alone.

      Tourbillions were created to offset the gravitational pull on conventional watch designs because of physical gears being used.

      How exactly is gravity, a factor here?

      • by MrKaos ( 858439 )

        But at that precision, the clocks in those places won't be the same. If only due to gravity variations along the planet's surface alone.

        Tourbillions were created to offset the gravitational pull on conventional watch designs because of physical gears being used.

        How exactly is gravity, a factor here?

        Look at any analogue clockface and you will realize that there is 30 degrees between each hour.

        Seconds can be measured by swinging a pendulum at a 30 degree arc for a wavelength of 2 seconds or a frequency of 1 second. If it is any more or less than +/- 15 degrees the amplitude changes and it is no longer an accurate representation of a second. Perhaps the wavelength is why a second is called a "second" instead of a "first" - but that's me speculating about words, the numbers are far more interesting.

        • which also is the radius and diameter of the sun in miles, respectively.

          No, they're not. The distance is off by 4 orders of magnitude.

          The first is when the structure is viewed from the corner the length of each of the two angle sides of triangle you are presented with is is 43200 feet for a total of 86400 feet with both sides combined.

          The length of the sides of the Great Pyramid is about 755 ft [wikipedia.org], not 43200.

          You're spouting Time Cube-level nonsense.

          • by MrKaos ( 858439 )

            The most accurate pendulum swings 43200 times for 86400 seconds in a day which also is the radius and diameter of the sun in miles, respectively.

            No, they're not. The distance is off by 4 orders of magnitude.

            No, I'm off by 1 order of magnitude, there is no need to exagerate.

            From the third sentence on Wikipedia's page on The Sun [wikipedia.org]: Its diameter is about 1.39 million kilometres (864,000 miles). Thanks for pointing that out.

            The first is when the structure is viewed from the corner the length of each of the two angle sides of triangle you are presented with is is 43200 feet for a total of 86400 feet with both sides combined.

            The length of the sides of the Great Pyramid is about 755 ft [wikipedia.org], not 43200.

            I said the the two angle sides of triangle and you are referring to one base length. If you check those numbers you would find that adding *both* base numbers presented to you (as I said viewed from the corner where you can see two bases) is 755 + 756 feet is 230+230 metres = 460 metres, whic

            • I did parse the first sentence incorrectly, I misread it as "radius and distance" instead of "radius and diameter".

              The radius of the Sun [nasa.gov] is 432380 miles. If we ignore the orders or magnitude that's close, but not a match.

              "the length of each of the two angle sides of triangle you are presented with is is 43200 feet" is just plain incorrect. It's 755 ft per side.

              Your point about Earth's rotational speed makes more sense now that you show your calculation, but the rotation speed at the equator is 463 m/s.

              My po

              • I think you are reading more than warranted into a few coincidences that require careful selection of units to line up

                One of these days - after Egypt removes the death penalty for people like me from their statute book - I'm going to go to the Great Pyramid, raise a glass of beer to Imhotep, then measure the sides for myself. That'll give me 4 values, all different, and I can derail any pyramidologist for the rest of eternity. It'll save so much effort in the long run. And I quite like the idea of visiting

                • I think you are reading more than warranted into a few coincidences that require careful selection of units to line up

                  One of these days - after Egypt removes the death penalty for people like me from their statute book - I'm going to go to the Great Pyramid, raise a glass of beer to Imhotep, then measure the sides for myself.

                  I'll save you the trouble. You will need the J.H Cole Study [ronaldbirdsall.com] which is more accurate and has been verified as opposed to the Howard Vice or the "corrected" measurements which cause information to be lost. And you would have to raise a glass to Isis, wife of Osiris, so it's probably not a good idea to piss her off.

                  and I can derail any pyramidologist for the rest of eternity.

                  Well they're concerned with the alignment to Orion, I'm more interested in the numbers I can see. It's not a full time job, I just use bc and bash to help me figure things out.

                  That'll give me 4 values, all different,

                  True, because they al

                  • No error bars on any of those numbers? That is, and I use this word carefully, incredible. Not believable. All measurements have uncertainties associated with them.

                    By the way, I've no interest in Orion, except as an astrophotography target.

                    • by MrKaos ( 858439 )

                      All measurements have uncertainties associated with them.

                      They are certainly a lot smaller than anything you're going to achieve by going there and doing them yourself. You are not going to get any better than a government funded project to survey those structures. You are talking about less than a millimetre error, you are *literally* splitting hairs.

                      Are you suggesting that there is a government conspiracy to publish fake dimensions of the Great Pyramid?

                      No error bars on any of those numbers? That is, and I use this word carefully, incredible. Not believable.

                      Yet the numbers are there mocking your dogmatic skepticism, twice, so I don't care what you believe. Perh

              • I did parse the first sentence incorrectly, I misread it as "radius and distance" instead of "radius and diameter".

                Ok, please keep in mind that I was posting tired about stuff I looked into several years ago, I'm not perfect either. Have you verified my claims about the pendulum? A 1 meter piece of string and a suitable weight is enough to verify my claims.

                The radius of the Sun [nasa.gov] is 432380 miles. If we ignore the orders or magnitude that's close, but not a match.

                Please consider the following three contextual pieces of information. 1. Ancient Egyptians didn't have the same equipment that NASA does. 2. The size of the Sun *changes* over time. 3. Where is the surface of the sun vs the atmosphere of the sun begin and end.

        • Thank you for elaborating as to all of the challenges we've incurred to justify a tourbillion to increase accuracy on physical movements.

          NOW tell me exactly what all of that has to do with measuring time at the atomic level using incredible frequencies.

          Even the "old-fashioned" cesium atom refresh rate of 9 billion ticks per second, isn't exactly challenged with gravitational pull.

          • by MrKaos ( 858439 )

            Thank you for elaborating as to all of the challenges we've incurred to justify a tourbillion to increase accuracy on physical movements.

            You're welcome.

            NOW tell me exactly what all of that has to do with measuring time at the atomic level using incredible frequencies.

            As I said: this is different from what the OP is suggesting however you can try this experiment yourself . I don't have an atomic clock handy to try the experiment myself. A one metre piece of string and a rock might cost about 1 cent. An atomic clock costs?

            • An atomic clock costs?

              There was a commercial one a couple of decades back which was in the "Rolex" range of prices. Steep, but not "sell your house and second-favourite child" steep.

      • > How exactly is gravity, a factor here?

        Higher gravity slows down time. No, seriously. That's part of relativity. If you take two identical clocks and put one on the moon for a year, then bring it back, the one that was in the low-gravity environment will have gone forward more. (Though it will tick more slowly during the high G forces of the trip to get there).

        In my mind, the analogy is people moving around in a tank of Jell-O and another group in an empty tank. Moving through Jell-O slows everything

    • by fazig ( 2909523 )
      You know, sometimes, bothering to read TFA can be helpful.

      [N]etworks of clocks like this could also be used as super-sensitive sensors -- to possibly detect a passing wave of dark matter, and to test Einstein's theory of relativity .

      So it's not a problem, like your wording makes it sound, it's an intended feature.

      • Yup. The times when someone did a shit job writing the TFS.
        • I look forward to reading your excellently-written summaries.

          Hmmm, is that 15 I count [slashdot.org]? Well, better than some, I'll grant. But you've seen nothing sufficiently stimulating in the last 2.5 years? Or do you just want to put up with my badly-written ones?

          • lol touche and my comment was nitpicky for this particular summary.

            This came on the heels of another story with an actual clickbait/teaser summary. There have been several of those hitting the front page lately. The summaries required clicking the referenced article for the stunning conclusion instead of summarizing it. This struck a nerve only because it similarly requires reading TFA. I admit, a small technical misrepresentation of a science/technical detail isn't fairly compared to clickbait blatantly sh
            • It's hardly a new problem. That's why I started submitting stories I found interesting some time in the early years of the millennium. I don't think I did it while I was on dial-up, because there isn't an asynchronous way of submitting stories.

              What is the beef with NPR? I thought it was one of the few advertising-free sources in the States, and therefore one of the few possible considerations for reading. Not that I actually have time to go across the ocean for news.

              • "What is the beef with NPR? I thought it was one of the few advertising-free sources in the States"

                They have a hard political bias and are not advertising free. They happened to be the news source on the other side of a recent clickbait summary.

                Of course most of the US media has gone off the deep end lately.
                • "gone"?

                  And "lately"?

                  The way it presents itself on this side of the Atlantic, the overwhelming majority of American media has been stark staring insane since ... as far back as I can remember. It explains a lot about the average American. Though when you get to know them, not all of the insanity is consequent on the media - some seems to be home-made. Hah - I remember one whole crew of Americans who refused to leave their hotel rooms on the way to or from work and missed all the fun of travelling abroad fo

      • I wonder how practical it would be to make a bunch of these things, stick them in a rocket and launch them into a few very high orbits. Might get interesting data out.

        • by fazig ( 2909523 )
          Probably not a high priority right now because we already have some lower precision atomic clocks up there, some of the most recent news concerning this being:
          https://www.sciencemag.org/new... [sciencemag.org]
          https://www.space.com/nasa-dee... [space.com]

          At those altitudes their precision is sufficient to make effects of gravitational time dilation apparent. And we can go back even further to where GPS was first introduced. Without compensating for both effects that are described by Special and General Relativity's time dilation,
    • That's one of the applications listed in the abstract. If we can have incredibly accurate clocks at different locations, we can measure differences in terrestrial gravity. This is potentially useful for a LIGO like experiment for density changes instead of gravitational waves.

  • ...It takes BeauHD to make love to a woman.
  • by Admiral Krunch ( 6177530 ) on Tuesday March 30, 2021 @03:57AM (#61216384)
    With more accurate clocks we might also be able to tell if physical constants are actually constant. [abc.net.au]
  • The "So What Factor" (Score:4, Interesting)

    by ytene ( 4376651 ) on Tuesday March 30, 2021 @05:01AM (#61216480)
    I'm pretty sure that this won't be the only reason the scientists are looking to improve accuracy, but I noted a comment in the linked article that mentioned GPS.

    I went digging and found this article [gpsworld.com], which notes that current GPS technology, when used with a handheld device like a smartphone, can be accurate to approximately 5 metres. The article discusses ways to improve this.

    Now, if the limiting factor on GPS accuracy was time measurement, then improving the accuracy of atomic clocks by a factor of 100x might in theory improve the accuracy / resolution of GPS down. Now, it likely isn't appropriate to suggest that the accuracy would improve from 5 metres to 5 centimetres, for a bunch of reasons, not least of which is our ability to put a GPS satellite in to an absolutely *perfect* geosynchronous orbit. For example, Wikipedia's article [wikipedia.org] notes that satellites we think of as being in immobile, geosynchronous positions may in fact still trace a path, often seen as a "figure of 8" from Earth, due to various orbital eccentricities. These variations would have to be factored in to GPS calculations as resolution increases, because the timing differences caused by the satellite moving become more relevant as resolution improves.

    OK, but would a 5cm resolution be more useful than a 5m one? Well, if you're driving to an unfamiliar address, the answer is almost certainly in the negative. But if you're a farmer and you're using GPS to auto-navigate your tractors or other farm machinery when it is seeding or spraying crops, then that accuracy might be really valuable. (In fact, it's so valuable that sometimes farms use local or "wifi range" transmitters to bounce signals, using fixed locations like fence posts as reference points. So maybe hyper-accurate GPS, as a product of more accurate time measurement, might actually be worth having...
    • > current GPS technology ... can be accurate to approximately 5 metres.

      It is important to note [gps.gov] the difference between UAE (User Range Error) which is < 0.715m 95% of the time, and UA (User Accuracy) which is 5m under open sky but can have centimeter accuracy with dual-frequency receivers.

      High-end users boost GPS accuracy with dual-frequency receivers and/or augmentation systems. These can enable real-time positioning within a few centimeters, and long-term measurements at the millimeter level.

      The accu

    • I do not think GPS is the main benefit for this especially in consumer grade hardware. They are too many variables in that use case to get 5cm precision. Really this is to help with scientific instrumentation where the precision and accuracy really matters.
    • Anybody needing extremely accurate positioning can use Differential GPS to get down to a couple of centimeters accuracy in real time. For recorded coordinates, they can be post processed against recorded differential GPS values to get centimeter accuracy.

      --
    • not least of which is our ability to put a GPS satellite in to an absolutely *perfect* geosynchronous orbit.

      There's no such thing. Well, not unless you're able to remove the Moon from the question. And Jupiter, Saturn and the other planets down to (however low a mass you want to go).

      Then you'll need to stop Earth from having earthquakes, which change the shape and distribution of mass in the Earth. Better stop mass moving from, say, the Greenland ice sheet to the Atlantic.

      In fact, it's so valuable that so

  • Hasn't relativity been tested enough already?

    One thing for sure, with all this testing, physicists don't work in the software industry. In theory, software has to be tested completely, at multiple levels, but these practices are like dark matter, supposedly everywhere but no one has observed it.

    • Hasn't relativity been tested enough already?

      This phrase does not mean what you think it does. People aren’t making the same types of measurements as hundreds or millions of other scientists and think they are going to turn anything up, it’s effectively been proven within measurement accuracy for those already. They test using things like higher energy levels, or on shorter time scales where people haven’t tried testing the relevant physics model. We know that relativity breaks down, but are unsure exactly where the theory starts

  • I am not a physicist. Now time dilation occurs between objects at different heights due to the effects of gravity. I read somewhere that the effect has been experimentally measured for height differences on the order of 1m. At what point to we need to take that into account when defining the second (i.e. do we define it by an optical atomic clock at a specified acceleration-due-to-gravity). That's the sort of thing that goes through my head when I read about this. I'm sure the physicists have it worked out

    • by necro81 ( 917438 )

      time dilation occurs between objects at different heights due to the effects of gravity

      An atomic clock's definition of the second would be equally valid far out in empty space as it would be in close proximity to a black hole. that is the core concept of relativity: the laws of physics are true no matter what your reference frame. Within each clock's reference frame, using that clock to define the second would yield perfectly consistent results for any experiment where you needed to measure the passage

      • The difficulty is in comparing the clocks for accuracy. Yes, you need to take more than just elevation into account, you need an accurate reading of the local gravitation - something that is inconsistent at a given altitude. It’s actually so difficult to compare clocks accurately that tons of assumptions had to be made. For example, we can’t to this day prove that light has the same speed in every direction, only that a round trip is the same in any direction.
        • by guruevi ( 827432 )

          Well, we don't have to prove that light is the same speed in every direction as in our reference frame and all other systems we've explored, it is the same. If the math works out the same, you can interpret it any way you want.

          • You misunderstand, there has been no experiment able to show the one way speed of light, not a single one accredited and accepted as main stream. It was an original assumption by Einstein. The math does not work out the same, there are major consequences and implications if the assumption that it is the same speed in every direction is not true - but we have yet to create a test or to show that such a measurement is intrinsically unmeasurable (outside of the difference cancelling in current situations)
      • Thanks for your post about reference frames.

        Let's do a quick thought experiment.
        Four friends agree to meet for dinner.
        They all leave their house at the exact same time.
        They all walk exactly 4 MPH.

        Friend A arrives and waits 3 minutes before friend B arrives.
        Friend C arrives 3 minutes after that.
        Friend D four minutes later.

        Knowing they all went the same speed, we know the restaurant is closest to friend A's house. Since friend B arrived next, they're house is the next-closest. It took friend D a long time t

        • by necro81 ( 917438 )

          I believe THAT is how GPS works. It's not related to different reference frames. It's simply that if you get the pulse from satellite M before you get the pulse from satellite X, you must be closer to M.

          You are correct; I mis-stated: GPS is more about triangulating distances from you to the satellites. However, the calculated distance to each satellite relies on the broadcast timestamps from each satellite; which are all in different reference frames (moving at different velocities, different gravitation

  • by dwater ( 72834 )

    So light will travel faster than the speed of light?

  • "What resulted is a more accurate comparison of these types of atomic clocks than ever before. [N]etworks of clocks like this could also be used as super-sensitive sensors -- to possibly detect a passing wave of dark matter, and to test Einstein's theory of relativity.
    "

    OUTCOME?

    A Slashdot summary is not supposed to be a teaser for the article but rather a condensed spoiler.
    • A Slashdot summary is not supposed to be a teaser for the article but rather a condensed spoiler.

      Welcome to the Internet. You must be new here.

      It's called clickbait. It's a global scourge, but as long as advertising pays for things (another and much older global scourge), it's inevitable.

      • Sure but Slashdot isn't the one who benefits from advertising in the external story. Which is why TFS is normally a summary and not a teaser. Teaser summaries have been appearing with increasing frequency in the past couple weeks. I'd hate to see the site ruined.
  • Am I going to need to buy a new watch?
  • Scientists are NOT inching closer, they are millimetering closer!

  • I'd think they'd be getting closer to defining the duration of a second. No unit of length seems appropriate for time, but perhaps that's just me...
  • Theyâ(TM)re going to redefine the second?!?
  • All y'all got some pretty funny remarks here. A few good chuckles.

    Yet, on a serious note, since our 'second' is based on fractions of the period it takes our planet to orbit the Sun
    and spin on it's axis, is it not time (no pun intended) to discover a more universal time period?

    Perhaps something based on the Planck length and the speed of light?
    Let's base it on the time it takes a photon to travel 1 Plank length in a pure vacuum.

    Then, of course, scale up from there.

    Seems it might better serve the u

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