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Science

Kilogram Gets a New Definition (bbc.com) 187

Scientists have changed the way the kilogram is defined. Currently, it is defined by the weight of a platinum-based ingot called "Le Grand K" which is locked away in a safe in Paris. On Friday, researchers meeting in Versailles voted to get rid of it in favour of defining a kilogram in terms of an electric current. From a report: The decision was made at the General Conference on Weights and Measures. But some scientists, such as Perdi Williams at the National Physical Laboratory in the UK, have expressed mixed feelings about the change. "I haven't been on this project for too long but I feel a weird attachment to the kilogram," she said. "I think it is such an exciting thing and this is a really big moment. So I'm a little bit sad about [the change]. But it is an important step forward and so the new system is going to work a lot better. It is also a really exciting time, and I can't wait for it to happen."

Le Grand K has been at the forefront of the international system of measuring weights since 1889. Several close replicas were made and distributed around the globe. But the master kilogram and its copies were seen to change -- ever so slightly -- as they deteriorated. In a world where accurate measurement is now critical in many areas, such as in drug development, nanotechnology and precision engineering -- those responsible for maintaining the international system had no option but to move beyond Le Grand K to a more robust definition.

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Kilogram Gets a New Definition

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  • excitement (Score:3, Insightful)

    by phik ( 2368654 ) on Friday November 16, 2018 @11:06AM (#57655682)
    This is good, and very important. But exciting?
    • by sjbe ( 173966 )

      This is good, and very important. But exciting?

      To people who deal with precise measurements yes it is very exciting. Maybe not to you but certainly to some of us.

    • Re: (Score:2, Funny)

      Comment removed based on user account deletion
    • Re:excitement (Score:5, Insightful)

      by orlanz ( 882574 ) on Friday November 16, 2018 @01:46PM (#57656840)

      Yes. Very much so. Even to those outside the field. To officially, precisely, and accurately say something is a "kilogram" our current method was well over a hundred years old and basically sneaker net.

      You took a clone of the official standard and compared it against that. The clone couldn't be directly touched, couldn't overly jostled, had an expiration, sits in a double vacuum, and had to be physically moved in proximity to what was being measured or, more likely, calibrated.

      With this method, you can build a simple machine (Kibble balance) [nearly] anywhere in the universe, calibrate it, find its measuring relationship to the universal constants, and you can figure out the "kilogram". THAT IS AWESOME.

      Layman terms: Before, you had to say "I want this many rocks worth of your stuff." Followed by handing over the rocks. Now you can say "We both know what 1 and 3 are. I want 15 of what you got."

      The measurement of how much of something you have, the kilogram, officially stands at the same level as the Meter, Second, and Temperature. All of which are based on universal constants and not the measurement of some useless fool's biology.

      • Also, very importantly, this method yields a constant reference. The old kilogram could be losing or gaining weight, and you wouldn't really be able to tell for sure.

      • by Anrego ( 830717 )

        Lets get full on pedantic.

        I read your explanation and while I found it interesting, I did not however find it exciting. I suspect this reaction is probably common among most of the geek audience here.

        A small subset of readers (and people within the general population) who deal with precise measurement and may be directly or indirectly effected by this may have become excited, but to most the reality that what we refer to as a kilogram is ultimately derived from a brick locked up in a vault somewhere in Fran

  • The strength of the earth's gravitational field varies. If you are using a Kibble balance to calibrate your weights, how do you compensate for that? Your kilogram mass will vary from location to location.
      Google: earth gravitational field
    https://earthobservatory.nasa.... [nasa.gov]

    • Re: (Score:3, Informative)

      by thegarbz ( 1787294 )

      By it's very definition a balance in independent of gravity. The balance will remain the same and that 1Kg *of mass* will work just as well if you try this experiment on Jupiter.

      • In this case, the balance works by applying a magnetic field on one side, not a weight, so it's not independent of gravity.

        • so it's not independent of gravity

          Magnetic fields have an effect on gravity so small as to not be relevant even at the precision we are talking about. This effect is relative to the existing gravitational field and above all ... kibble balance. Unless you make the balance 588 million km wide and have one side of it on Jupiter and the other side here on Earth, no the measurement is for all intents and purposes including those requiring the defining of an SI unit, independent of gravity.

          • That was not my point. My point was that it's a balance with a magnetic force on one side, and a weight on the other. One side is independent of the gravitational field, the other side isn't. In order to use the Kibble balance, you need to first measure local gravity and calibrate that.

            • Tea you have to measure locally gravity to calibrate the kibble balance. Apparently that can be done to better than 1e-8 accuracy by measuring the acceleration of a free falling body.
              • How do they account for the movement of the moon? It effects the tides so I would think it is not insignificant. And the moon moves, when you weigh something the moon won't be where it was when you calibrated the scale.
            • Right I got you now.

      • by 93 Escort Wagon ( 326346 ) on Friday November 16, 2018 @11:42AM (#57655934)

        By it's very definition a balance in independent of gravity. The balance will remain the same and that 1Kg *of mass* will work just as well if you try this experiment on Jupiter.

        Although if you’re attempting this on Jupiter, you’ll likely be distracted due to asphyxiation and crushing pressure - so work fast.

      • by swillden ( 191260 ) <shawn-ds@willden.org> on Friday November 16, 2018 @12:24PM (#57656264) Journal

        By it's very definition a balance in independent of gravity. The balance will remain the same and that 1Kg *of mass* will work just as well if you try this experiment on Jupiter.

        But a Kibble Balance isn't that sort of a balance. It's a "single pan balance" which balances gravitational acceleration against acceleration caused by a magnetic field. So the Kibble Balance is very sensitive to changes in the gravitational field.

        Luckily, it's possible to measure the local force of gravity with extreme precision, without reliance on the definition of the kilogram. It's done with dropping-mass gravimeters that measure the deflection of a laser beam, so it only relies on standard units of distance and time, and the speed of light as measured in terms of those units, not on the definition of mass. Obviously this is crucial or else you'd need a definition of a kilogram in order to calibrate your Kibble Balance.

        So you can do this on Jupiter just fine, but you first have to measure the local gravitational field and adjust the amount of current you feed the Kibble Balance to balance against your kilogram test mass.

        The biggest downside of this new method of defining the kilogram is that turning the definition into a measurement is incredibly precise and difficult work. It's so expensive to do correctly that for the foreseeable future there will probably only be a handful of wealthy countries who bother to do it. This means that for practical work, the definition will just be used to calibrate the exemplars that are used today, and everything else will continue as always. But it does mean that we now have a definition which is independent of those exemplars and guaranteed to be perfectly unchanging as long as the Planck constant remains constant.

        • It's a "single pan balance" which balances gravitational acceleration against acceleration caused by a magnetic field.

          Except it has a resting state where gravity acts on both sides of the balance which gives you effectively a calibrated zero independent of any gravity. Unless the gravity on one side of the balance is different from the gravity on the other side. ... And if that is an issue it would probably be a good idea to see if Gordon Freeman is standing behind you whacking things with crowbars.

      • By it's very definition a balance in independent of gravity.

        No it is not. Even a standard balance relies on the gravitational field for both sides being equal and, if you get precise enough, this may not be true. However, the watt balance balances the force of gravity with an electromagnetic force. Part of the measurement also requires determining the local gravitational field but this is something that you can measure accurately which is why this is still a far better definition than using a lump of metal outside Paris.

    • There are techniques to measure local gravity field without calibrated weights. For instance, you can measure the time it takes for an object to fall.

    • by novakyu ( 636495 ) <novakyu@novakyu.net> on Friday November 16, 2018 @11:40AM (#57655914) Homepage

      Yeah, they should have left out the Kibble balance part. That's more confusing than illuminating. In terms a layman can understand, kilogram is now defined the same way meter is: by defining a related physical constant to be an exact value.

      Meter is defined today not by a physical object, but by defining speed of light to be exactly 299,792,458 m/s (that is, in significant figure terms, there are significant zeros following the decimal for-ever). With time defined by the atomic clock standard, this definition of speed of light also defines what a meter is (and many different experimental arrangements can be designed to use this relationship to actually calibrate real object).

      With the vote today, kilogram is now defined by defining Planck's constant to be exactly 6.626070040 * 10^-34 kg*m^2/s (um, Wikipedia's not updated yet; the exact value they chose might be different from this number; important thing is that the value they chose now has infinite number of significant figures). Since meter and seconds are already defined, defining this constant defines the kilogram, and clever experimentalists can come up with better methods than Kibble balance for calibrating any local kilogram standards.

      P.S. BTW, for scientists working in precision measurement area (the area NIST and NSF funds as they relate to fundamental science), this is an exciting news. It's a validation of accomplishments of their field, on the same (or possibly greater) magnitude was when atomic clock standard was adopted for the definition of second.

      • infinite number of significant figures

        First thanks for the explanation, but are you sure your meant 'infinite'?

        • by mrvan ( 973822 )

          Not OP, but I'm pretty sure the answer is 'yes': the whole point is that it is not 299,792,458.00, or 299,792,458.000, but *exactly* 299,792,458, so with as many zeroes after it as you wish that are actually significant.

        • infinite number of significant figures

          First thanks for the explanation, but are you sure your meant 'infinite'?

          Unlimited is probably a better word.

        • First thanks for the explanation, but are you sure your meant 'infinite'?

          Yes, it is a definition, not a measurement. Essentially we define the fundmental, unchanging constants of the universe as so many SI units and then use measurements to precisely define the individual units. In fact, in particle physics, we actually start by defining these fundamental constants as '1' unit each and then derive units for energy, momentum, mass etc. from them creating a system known as "natural units". It's not very practical for everyday quantities but very useful if you are dealing with fun

    • by idji ( 984038 )
      You need to calibrate your Kibble Balance with an accelerometer which needs calibrating from your cesium clock and krypton-86 laser.
      But the kilogram is now defined by the Ampere, which is defined as the current which creates a Force of 2×107 newtons per metre between wires 1 meter apart. but how do you measure a Force without knowing what a kilogram is?
  • by religionofpeas ( 4511805 ) on Friday November 16, 2018 @11:23AM (#57655784)

    How many times do you need a very precise absolute measurement in drug development or nanotech ?

  • by SlithyMagister ( 822218 ) on Friday November 16, 2018 @11:25AM (#57655798)
  • Do they have a guaranteed efficiency vs electric input? Or does this not somehow apply?

    Doesn't each kibble scale require calibration whenever the altitude changes? What do they use as a reference for calibration since it appears even the Kg reference is not stable?

    - Yep I got plenty of dumb questions.
    • The Kibble balance uses measurements of voltage, current, velocity and gravitational acceleration in order to calculate the mass that was placed on the balance. Here's the maths [vox-cdn.com] involved.

      Then it's likely that those measured masses will be used to calibrate other equipment, as is done now with reference masses that were compared to Big K.

  • by sjbe ( 173966 ) on Friday November 16, 2018 @11:51AM (#57655988)

    Basically what they did was they defined Planck's constant to be a fixed value pretty close the the calculated number previously used. So instead of calculating Planck's constant from an arbitrarily defined kilogram they define the kilogram (and a few other constants) from an arbitrarily defined Planck's constant. This takes the error bars away from Planck's constant and the other fundamental measurements fall out naturally as a result to precisely defined and fixed numbers.

  • Please don't make the metric system stop making sense. We already have a nonsensical measuring system, here in the U.S. .
  • Veritasium (Score:4, Informative)

    by SCVonSteroids ( 2816091 ) on Friday November 16, 2018 @11:57AM (#57656056)

    Our friend at Veritasium does an excellent job breaking this down:
    https://www.youtube.com/watch?... [youtube.com]

  • The hunk of platinum called le Grand K that defined the kilogram is not the standard anymore.

    A Kibble balance, that will define the kilogram will built using platinum, iridium and other exotic metals. It will be housed in the double walled basement of SI building. This le Grand K(ibble) will be the standard Kibble balance against which all othe Kibble balances will be measured and tested against.

    • The difference is that you can build additional Kibble balances from scratch, without using the existing ones as reference.

  • A moment is defined as kg.m^2

    The new definition is thus a unitary moment per unit area.

  • by jd ( 1658 ) <imipakNO@SPAMyahoo.com> on Friday November 16, 2018 @04:52PM (#57658070) Homepage Journal

    The second is out of date. Caesium is a horribly outdated method of measuring time. Modern atomic clocks, using strontium quantum gasses, are roughly ten orders of magnitude better.

    But because of how the second is defined, you can't use a more accurate clock. The errors in caesium clocks are part of the definition. Remove the error and you're not measuring seconds even if you're measuring more accurately.

    It's probably better to use fundamental units as the starting point, or at least something close, rather than arbitrary objects in nature.

    Ideally, it shouldn't matter if things get measured more accurately, you won't break anything.

    If you can't do that, then the definitions should be aiming at the ten orders more accurate results that can be obtained.

    As for constants, they should be justified geometrically, kept simple, or defined in terms of underlying physics.

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