NIST Wants An Electronic Kilogram 270
Dearing writes "According to the Global Engineering Journal, NIST, those not-so-standard standards people, want to give up the hunk of metal they've been calling a kilogram, even though it never weighs the same twice. In it's place, an electronic kilogram could act as the permanent standard."
The ultimate diet hack (Score:5, Funny)
Why aren't I thin now? I must hack the electronic tape measure next.
$10 if you want me to make you taller, too.
Re:The ultimate diet hack (Score:5, Funny)
Re:The ultimate diet hack (Score:1, Redundant)
Re:The ultimate diet hack (Score:2, Insightful)
Damn kids... (Score:5, Funny)
Re:Damn kids... (Score:4, Funny)
Well, we had it toof. We didn't have any of this metric rubbish. We used the stone-furlong-fortnight measurement system. Everyone had to lug around a big stone and a flatulent racehorse for two weeks just to measure something. A platinum-iridium cylinder? Luxury!
Re:Damn kids... (Score:2)
Re:Damn kids... (Score:2)
What? (Score:4, Interesting)
They balance it against gravity to measure it? Wouldn't that be really, really inaccurate, since gravity varies by altitude, local density variations, etc? Did I misunderstand what I just read?
Sheeze, why not just define it as 1.498e20 atoms of carbon (or whatever number), and be done with it.
Re:What? (Score:4, Funny)
No problemo - as soon as you figure out a practical method for counting out those atoms on the floor of your typical machine shop. 'Oops - dropped another one. Someone blow the oil off it NO NOT THAT HARD - damm, out the window'.
sPh
Re:What? (Score:2)
Well, clearly it must be harder than I think, since they would have done it that way a long time ago if it were easy.
But still... wouldn't you know the volume that so many atoms of a material would take if you melt it and form it under certain conditions (e.g., zero pressure)? Once you had a block, you could cut it to exact dimensions using lasers. Presumably we have very accurate way of measuring the meter, so we ought to be able to do very precise cuts.
Re:What? (Score:2)
Re:What? (Score:2)
You would need a stepper capable of moving an atom at a time.
We've got them: how do you think they move a STM tip? They're piezoelectric.
There's other problems with this though: the chances of cutting a clean, macroscopic edge are basically nil.
Eric
Re:What? (Score:2)
Well, I guess all those chip manufacturers will be a little ticked that they spent all that money on extremely-well calibrated factories... NOW you tell us!
Re:What? (Score:2)
Re:What? (Score:2, Informative)
"They balance it against gravity to measure it?"
The article linked to makes it sound that way, but if you have an electronic measurement for force (which is what the "electronic kilogram" is - see the excellent page [nist.gov] posted by aktbar), and you have other standards for the meter (certain number of wavelengths of a certain light) and second (certain vibration of some molecule, I'd have to look up the details), then F=ma (force = mass times acceleration) lets you derive the kilogram. (in units terms, Newtons = kilograms times (meters per second squared) - if you have newtons, meters, and seconds, then you get kilograms).
"Sheeze, why not just define it as 1.498e20 atoms of carbon"
This approach has also been investigated. See the Avogadro Group [nist.gov] or an article [nist.gov] summarizing it. These things boil down to what you can measure more accurately.
I visited NIST and had it explained (Score:5, Insightful)
The electrons since they are moving, produce a magnetic field which pushes against a well known reference magnetic field (which can be measured without concern for mass). This magnetic repulsion is used to balance a 1 kg reference mass against gravity.
Since gravity produces acceleration independant of mass (ma=F=mg => a=g), it's also possible to measure the local gravity to a high precision by means of the acceleration with needing to know something's mass.
Thus we have a way define mass in terms of a number of electrons (and a geometry of the path they take, technically) and other measured quantities which don't use mass in their standards.
You could say mass is so many atoms of some reference substance, but how do you measure it? Since you can't first weigh it and extrapolate from there. Similarly volume would depend on temperature, structural arrangement, and other things. The people at NIST claim this provides a more easily reproducible method of defining mass. (Of course I'd rather just stick with the electronic scale or balance pan since these tend to be accurate enough for me.)
Re:I visited NIST and had it explained (Score:2)
From then on if you need a highly precise measurement you can make kilograms my figuring out how much weight will balance when supported by be such and such current under these precise conditions. Alternatively you can find something's weight (and thus its mass after checking local gravity), by figuring what mulitple of the standard number of electrons are needed to balance it against gravity (everything else being the same).
We just start out by picking a number of electrons which is equivalent in this frame work to the standard kg so that we don't have to go through and change all the other things we've measured in the past, but we consider this the standard cause now anyone (with money and time) can go out and build a machine to tell him exactly how much a kg weighs, and you don't have to travel out there to measure a special cylinder.
Because. (Score:2)
Re:What? (Score:2)
We're not talking about spring scales and such, it's a beam balance. It compares the weight of whatever you're trying to find the weight of on one side to the weight of the official kilogram on the other. The idea is that, if the beam is level, the weight of the kilogram mass on one side is the same as the stuff you're measuring on the other, so the masses must be the same.
Sure, the gravitic attraction on the two samples will be slightly different over the length of the beam (say 8"), but the difference is disgustingly negligible.
Re:What? (Score:2)
At least, that was the explanation back when I took first-year physics. Presumably the accuracy of Avogradro's number will improve over time, but an extra 10 sig figs is a challenge . . .
Just a different was of measuring it (Score:3, Informative)
Re:Just a different was of measuring it (Score:3, Insightful)
No, they are just trying to make sure that the new mathematically "electrically" defined kilogram is as close as possible to the current kilogram.
The same way they redefined a second based on a certain number of rotations of a cesium atom (or something like that) and redefined a meter in terms of light-seconds. They got the new definitions as close as possible to their old values.
This is nothing more than doing essentially the same thing with the meter, however more difficult.
Re:Just a different was of measuring it (Score:2)
I'm not entirely clear on how they intend to deal with the mass vs weight issue, though. If the experiment has to be done in Earth's gravity at that particular spot, we'd have to throw the aliens the whole planet to explain anything...
NOT Just a different was of measuring it (Score:2, Informative)
The new standard is going to be "the ammount of mass properly balanced by XXX volts and YYY amperes in the referenced system." That ammount is expected to be more consistent than "the ammount of mass needed to properly balance that hunk of metal we have in the basement."
The current (physical) standard changes from time to time due to dust, wear(from cleaning), etc.
Can't use volts to define a kg (Score:2, Informative)
The new standard is going to be "the ammount of mass properly balanced by XXX volts and YYY amperes in the referenced system."
SI standards based on absolute numbers (as opposed to chunks of metal) include the second (9192631770 ticks of a cesium atom) and the meter (the distance light travels in 1/299792458 second). But you can't define kilogram in terms of volt or ampere because they're already based on the kilogram. A volt is one watt per ampere. A watt will raise a 1N weight at 1m/s, while a newton will accelerate a 1kg mass at 1m/s^2. An ampere is the current in two parallel wires 1m apart that produces 2e-7N per meter of length. Therefore, defining a kilogram in terms of a volt or ampere would be circular (unless NIST skillfully arranges the equation to solve for kg); NIST must define its new version of the kilogram in terms of the second and meter.
Sources include NIST's current definitions [nist.gov].
Re:Just a different was of measuring it (Score:2)
It would be charitable to let them know what its mass was first so it didn't destroy (or be destroyed by) whatever they were catching it with...
Re:Just a different was of measuring it (Score:2, Funny)
>
> If the dictionary weighs exactly one kilogram, we could kiil two birds with one stone...
Sheesh, it's about time. (Score:1)
If you're going to have standards, at least base them on constants, like the aforementioned speed of light for distance, the mass of certain molecules for mass, and...hmmm...can anyone think of anything for time? (I don't know what they currently use) Keep in mind that speed-of-light is taken.
Re:Sheesh, it's about time. (Score:1)
Time is already defined by the vibration of some atom. I forget which element at what temperature but that's how atomic clocks work
E=mc^2 (Score:3, Informative)
Second: The second is the duration of 9 192 631 770 periods of the radiation corresponding to the transition between the two hyperfine levels of the ground state of the cesium 133 atom. [nist.gov]
As mass and energy are equivalent, can't they just define the mass as a certain number of barrels of that cesium 133 light? Right now they just throw away that light each second [nist.gov], but they could recycle it.
the atom is krypton. (Score:2)
well duh (Score:2, Informative)
A gram is not a measurment of weight.
Re:well duh (Score:5, Funny)
It's a measurement of THC
no sir (Score:2)
Of course it never weighs the same... (Score:5, Insightful)
Re:Of course it never weighs the same... (Score:2, Insightful)
True enough, but if you want to determine the mass of a small object, how do you do it? Odds are really good you're going to weigh it in some manner, and divide by 9.8 m/s^2.
According to NIST [nist.gov], they've got a variance on the order of 3% per century in the observed mass (probably measured by weight) of the standard kilo brick.
Wow! I thought the recent news of observations that show that the fine structure constant or the speed of light may be minutely changing as the universe ages [yahoo.com] were pretty far out, but to think that mass is this variable...
Re:Of course it never weighs the same... (Score:4, Informative)
standard kilo brick.
3 percent??? Do you have any idea how HUGE a variation that would be in a primary standard? Maybe if they polished it with a belt sander before every measurement...
The link you provided says:
[...]are causing the mass of the kilogram to vary by about 3 parts in 108 per century relative to sister prototypes.
Now I'm not certain about this, but I'd wager that the "108" is actually a "10 to the 8th power" that got mangled somewhere in the conversion to HTML. If so, it would represent a more plausible 0.000003% per century variation.
Re:Of course it never weighs the same... (Score:3, Funny)
Actaully, most high-schools have this new high-tech thing that actually measures mass. It's called a beam balance. You have some known quantity on one side, and your unknown on the other, then you compare the two. Really revolutionary!
Also, 9.8 m/s^2 is only at sea-level. Raise your hand if you live a sea-level? That's what I thought.
This Guy is just a Geek ! (Score:1)
=> as Quake gets better, I can apply it to my hardware, wich may lead to a better quake, and so on
I think I understand ! I'am a potention Nobel Prize, Just as he's a Potential Quake geek !
Something's fishy (Score:1)
Call me a computer scientist, but isn't there something recursive about defining the prototype kilogram with gravity and then measuring gravity at the same time? Or is there something I don't understand about gravity?
Re:Something's fishy (Score:2)
There are ways of measuring gravity without a known mass standard. For example, you could measure the acceleration of an object falling freely in a vacuum chamber (only need length and time measurements).
However, it does seem strange to me that they'd base the kilogram standard on something as indirect as the local gravitational field.
Re:Something's fishy (Score:2)
For example, you could measure the acceleration of an object falling freely in a vacuum chamber (only need length and time measurements).
Only if you know your exact distance from the earth's center (as well as the earth's mass). How do you determine that? To measure G you need to use a torsion balance, and that requires a definition of kg (since G is defined in terms of N*m^2/kg^2).
Re:Something's fishy (Score:2)
From the description of the device, it relates the mass of the standard kilogram to an electromagnetic force, by balancing that electromagnetic force against the gravitational force on the mass (== the weight of the mass).
Therefore, the only relevant parameter is the one relating the mass of an object to the gravitational force on that object. This is "little g", the local gravitational acceleration, and it can be measured directly with only a length and a time standard. You don't need to know "big G" or anything about the earth.
The gravitational force on an object is given by:
Force(N) = mass(kg) * g(N/kg)
(note that 1 N/kg == 1 m/(s^2))
Re:Something's fishy (Score:3, Interesting)
If there isn't, then you're way smarter than most practicing physicists... gravity is hard.
Why not define in terms of other standards? (Score:2)
You could define a kilogram as the amount of water in a cubic decimeter. Or, you could define it as the mass of 6.02 * 10^23 protons, or any number of other ways. I don't understand how this measurement they intend to make with the device they have will be any more accurate or easier to deal with.
You could even define it as the energy in some huge number of photons of a particular wavelength. :-)
Re:Why not define in terms of other standards? (Score:5, Informative)
remember that the base physical units have to be directly related not to theor, but to empirical observation. That's the difference between "units" and "physical quantities"
MASS is a physical quantity. "kilogram" is a "unit" of that quantity. defining it in terms of the "mass of a proton" makes no sense because thats essentially a *circular* argument.
if you;re gonna construct a vast edifice of science, the foundation better be damn rigorous! this isnt just semantics, its essential, the way that we have to be absolutely sure that 2 + 2 = 4 (which can be derived from the Completeness property of the Real number Set). A good reference for basic units and quantities is here [amazon.com].
Re:Why not define in terms of other standards? (Score:2)
Wait! 2 + 2 = 3, not 4
Bleem lives on
-Todd
Re:Why not define in terms of other standards? (Score:2)
So, this means that you think the mass of a proton is going to change?
Using atomic fountains it's actually feasible to get well known number of protons together in a group that's possible to accurately measure the mass of. I think that basing it on something like this is an excellent way to define it. Simple, easy to intuitively grasp, and doesn't involve any hairy adjustments for gravity.
Re:NOT "circular" (Score:2)
Similarly, the kg could be defined as "the mass of 4.32415234895 x 10^33 protons (or whatever -- pulled that number out of you know where).
How is one supposed to accurately count 4x10^33 protons without allowing them to be bound into an atom (which decreases/increases the mass).
Re:Alright, fine (Score:2)
My main point was regarding the feasibility of using that as a reference. Transitions of cesium atoms or whatever the second uses is easy to measure using an atomic clock.
In any case, we already have a similar definition. "The mole is the amount of substance of a system which contains as many elementary entities as there are atoms in 0.012 kilogram of carbon 12." I guess it would be sufficient to simply pick a particular fixed number near 6.02x10^23 to be exactly equal to a mole.
the "mole" is not a unit, or a quantity (Score:2)
the "mole" is a CONSTANT which is a separate animal entirely from "units" and "quantities"
your analogy is flawed... constants are hybrid entities which in the end must be defined in terms of a unit. that's why the definition for mole is "some integer related to the definition of a kilogram"
Re:the "mole" is not a unit, or a quantity (Score:2)
Re:the "mole" is not a unit, or a quantity (Score:2)
You're right, but I think he meant that Avogadro's number is a constant, not a unit. According to your BIPM link [www.bipm.fr]>:
How many atoms there are in 12 grams of C-12 is a constant, which must be measured empirically, and thus cannot form an "idependent" basis of mass. Of course, we could define Avogadro's number to be exactly 6.022 x 10^23, or just 6 x 10^23 (the math is simpler, and isn't that what SI units are all about?) and say that however much that many atoms of C-12 weighs is 12 grams, but who'd want to count them?
Re:the "mole" is not a unit, or a quantity (Score:2)
thank you, thats what i meant to say, i was indeed talking about Avogadro's constant, not "mole"
Re:the "mole" is not a unit, or a quantity (Score:2)
How many atoms there are in 12 grams of C-12 is a constant.
No. If you define a kg as the mass of a certain object, and the mass of that object changes, then the number of atoms in 12 grams of C-12 also changes. If something changes, it's not a constant. Yes, you could define Avogadro's number to be exactly 6.022x10^23, but if you do that you have to either redefine the mole or redefine the kilogram. Presumably you would keep the definition of the mole and remove the definition of the kilogram, as defining Avogadro's number would in effect define the kilogram. Now you have the problem that your definition of the kilogram is essentially useless, since it's virtually impossible to count 6.022x10^23 atoms of C-12. We'd be better off with the definition we have now.
Ultimately scientists are trying to get a definition of the kilogram more like that of the meter or second. Something with a measurable integer or reciprical of an integer. At that point Advogadro's number will be a constant, but if it's turns out to be an integer we've probably discovered a brand new formula that was never discovered before.
SI units used to be about simple math, but more recently coming up with measurable references has taken precedence. I don't even think a cubic cm of water weighs a gram any more, actually I'm almost certain it doesn't. Close, but not exactly. Advogadro's number will probably wind up with a similar fate. Close to 6.022E23, but not exactly.
Re:the "mole" is not a unit, or a quantity (Score:2)
If something changes, it is not constant; it may well still be a constant. The value of constants may change as we improve empirical measurements or as the behavior to which they're tied changes (as the strength of the electromagnetic force changes, when it for example becomes distinct from the weak force, its constant changes). Constants are not variables in equations; they may be variable in real life.
Re:Volts and amps are kilogram-based, but... (Score:2, Insightful)
Then, volt = kg*m^2/s^3 per Q/s
Then, kg = volt*s^2*Q/m^2
So, as long as you have another standard for volt based on charge and time and the speed of light. Then, all measuring devices could be referenced against a charge standard and time standard.
Does that work?
Re:Why not define in terms of other standards? (Score:3, Interesting)
Do you know how many states of water there are? Not to mention somewhere you are going to have to define a pressure, a temperature etc. You don't exactly want to end up with a circular reference in there....
Now, at CSIRO [csiro.au], they are researching into using a super spherical ball of silicon, about 8 cm across, and weighing 1kg. It is spherical to an accuracy of 8nm, and was built by the same glass grinders that build lenses for our precision instruments and telescopes. We have shipped one or two overseas (and have one or two in .au), so that people around the world can test 'em.
Pretty cool in all - I watched the guy pick it up with cottonwool, in the same room that I was in - no contaminant free clothes, either - it is pretty robust. It is all part of an international effort to produce new standards of mass etc - the platinum bar in Paris is getting a bit old. IIRC - CSIRO are researching another method, but can't remeber what it was....
You could even define it as the energy in some huge number of photons of a particular wavelength. :-)
Hmmm - which unfortunately comes back to a density of photons, and a length cubed, which unforteunalty comes back to that damn platinum bar in Paris. IIRC - it has a chip in the corner of it too - Ooops. I just dropped your metre - my, how you have just grown!
The problem isn't definition. (Score:2)
Balancing it against a reference weight is one way.
What they are saying is, doing this electronically is more accurate and easier, using magnetic fields and measured currents and such rather than a classical balance.
The definition of a kilogram of mass isn't going to change. They're just finding a better way to measure it.
Re:Why not define in terms of other standards? (Score:2)
J
Re:Why not define in terms of other standards? (Score:2)
Damn, is Physics no longer a science?
Guess I'd better turn in my science degree then...
Cheers,
Tim
Re:Why not define in terms of other standards? (Score:2)
Stupid aliens (Score:1)
Yeah, because an advanced species capable of space travel would never understand something so complex as to think of a standard measurement of a physical item that isn't affected by gravity.
Re:Stupid aliens (Score:2)
Of course, you'd need more than the amp. There are a bunch (seven?) of fundamental constants, out of which all other units can be made. You'd need them all, and to communicate them, you'd need experiments that determine their value. So far, we have no such procedure for mass... so we couldn't calibrate the masses in the experiments.
It's not that the aliens are stupid. It's that we don't yet know how to communicate the value of a mass independent of a reference mass.
Oh, and by the way: The late doctor never said the aliens had space travel. Indeed, he implied the opposite: If we had to communicate from afar... using, I suppose, EM waves.
Re:Stupid aliens (Score:2)
"The metre is the length of the path travelled by light in vacuum during a time interval of 1/299 792 458 of a second" (17th CGPM, 1983, Resolution 1)
While the kilogram is still defined as:
"The kilogram is the unit of mass: it is equal to the mass of the international prototype of the kilogram" 3rd CGPM (1901)
Re:Stupid aliens (Score:2)
More information from NIST itself... (Score:5, Informative)
This really does make sense to replace the artifact with something independent -- they have a bunch of "voodoo" every time they measure the current kilo to try to get the same answer.
Re:More information from NIST itself... (Score:2, Informative)
voodoo... (Score:2)
Why? (Score:2, Insightful)
In reality, I'm sure we could at least replace it with a theoretical definition that's more accurate than the cylinder. Even though the current definition of the meter is physical, in practice it's difficult to measure (the distance light travels in 1/299,792,458 of a second).
So, define the kilogram as the amount of mass that one liter of pure water contains at 4C. We already know the definitions of the meter exactly (defined by scientists, thanks very much), electric field permittivity (\epsilon_0), magnetic field permeability (\mu_0), the speed of light (c), etc.
With all these constants defined exactly, it just seems like there would be a better way...
Re:Why? (Score:2)
So, define the kilogram as the amount of mass that one liter of pure water contains at 4C.
At what pressure? Your unit of pressure will need to be based on your unit of mass.
What this means to drug dealers! (Score:2, Funny)
This should be GREAT for police officers. Just look for two story tall electronic kilogram machines to bust all the coke dealers.
Can somebody explain ... (Score:2)
Re:Can somebody explain ... (Score:3, Informative)
Presumably, because of engineering imperfections in the (mechanical) measurement devices, and perhaps also due to local variations in gravity, caused by tectonic forces, tides, etc.
The bottom line is: weighing a physical chunk of metal is as poor a standard as measuring the length of a chunk of metal. We do better if we can relate these standards to invariant values derived from basic physics.
Re:Can somebody explain ... (Score:2, Informative)
The simple answer: The environment.
Its not just a matter of determining a fixed quantity of material. The machinery used to determine the measure is also affected by its environment. A room that increases its temperature by 1 degree is going to cause the spring to stretch that much further (or coil to conduct X more electrons).
Also, the Earth does not exert gravity at the exact same force at all points on the globe at all times. Gravity is "currently" one of the forces involved in the measure of weight.
Finally, the speed of the Earth's motion could produce some relativistic effects on the measure (although I'm not sure it would apply in this case).
When they're finished with the kilogram... (Score:2)
EKG? (Score:2)
Sorry, the acronym EKG is already taken. Please try again.
Note: masses expressed in '01 Kilograms (Score:2)
For example: "Pluto masses 1.203e12 Kg? Is that in 1993 or 2001 kilograms?"
Oh no, not again... (Score:5, Interesting)
That's odd, I don't understand how this question relates to an article about an electronic standard for mass. And before you flame me for nitpicking, let me remind you that Mars has some very expensive upper-atmospheric dust right now thanks to imprecise communication about units of force. Ordinary people can blithely confuse mass and weight without causing problems. Engineers can't, and this article appears in an engineering publication. When are we going to learn to be more precise about this sort of thing?
Re:Oh no, not again... (Score:2)
derive measures from physics constants (Score:3, Informative)
the fundamental constants of physics.
The two most popular are "c" the special of light
and "h" Planck's quantum of action.
A recent Physics today suggests a using
E=mc^2 and E=hv, where v is a frequency.
Frequencies are the most accurately measurable
item in the universe, at a current accuracy of
one part in 10^19. So the proposal is to choose
a "kilogram frequency" that precisely defines
the kilogram. There is already a "meter frequency"
that precisely defines the meter length in terms
of light velocity. And a "second frequency"
which some frequency count close to an astronomical
second.
The least well-known constant is the gravitational
constant, measured only to four decimal places.
The probably is instrumental error, because
everything pulls on everything else.
At least twice in the past decade someone has
proposed changing the law of gravitation because
of funny measurements, but every time an
experiment error was found. The constant "G"
doesn't fit into many physics equations,
so it isn't as easy to bootstrap equations
as for the other constants and measurement units.
not to be redundant, but (Score:3, Informative)
of course it weighs different every time, it's a standard kilogram, which is a measure of mass. the weight of the Kg will differ as gravity differs - which is a fun little trick having to do with the mass of the earth and the nearby celestial bodies.
the whole point of the new measuring device is (basically) to more accurately measure the force of gravity on the standard mass - by doing some magic with a magnet keeping the whole thing in balance. this is really just getting at a better measurement of gravity than anything else.
the crux of the situation is that the only standard for a kilogram is the actual lump of platinum itself. other things, like the standard second, are based on fun stuff like exactly how many times a cesium atom vibrates at a particular temperature. it might be fun to try and define a kilogram as Exactly This Many platinum atoms and be done with it, but that's kinda tricky for the moment.
it might be a better "standard" to accelerate the "standard" mass at a "standard" rate and measure the forces. say, by swinging the thing around in a calibrated centrifuge at whatever we're calling one Gee. then you can get to the bottom of the whole "weight" issue (in terms of newtons, i suppose).
besides, unless the standard mass is made of something that's decaying (radioactively - it's not like they'd make the thing out of, say, beef), it'll be pretty much the same mass for quite some time. it's just those nitpickety scientists at the NIST (on which i read a very interesting article recently, i believe in National Geographic Magazine) who want it to be defined in terms of something that will never change
and secondly, since when is the NIST "not-so-standard"? they are the national frickin' institution for the damned things, so they should be an authority on the subject...
Re:not to be redundant, but (Score:2)
Suppose it isn't. Suppose an anti-metric-system terrorist manages to shave a chunk off the standard kilogram and swallow it. What then?
The basic idea of making a reproducable standard is a really good idea. Right now, the US has a standard kilogram that is a careful copy of the master standard kilogram, but how can we be completely sure it's an accurate copy?
I'd be interested, once they get the new standard sorted out, to have them check the US standard kilogram and see to how many decimal places it is accurate.
steveha
Buncha science sissies (Score:3, Funny)
There's a guy on the corner what can measure out quarter and half ounces with amazing consistancy... dunno why they have to go to all that trouble, when they could hire this guy cheaper.
Betcha if scientists were wont to shoot NIST people if their measurement vehicle was wonky because NIST's dumbell was off, you'd see some pretty accurate measuring going on over there...
Standard kilogram (Score:2, Insightful)
This reminds me of when a previous physical-object based basic measurement standard was updated, the meter. Instead of being "one/ten-millionth of the distance from the equator to the north pole along a meridian through Paris" (http://www.surveyhistory.org/the_standard_meter.h tm), the measure was eventually (after a couple of rounds of revisions) standardized to be the distance light travels, in a vacuum, in 1/299,792,458 seconds with time measured by a cesium-133 atomic clock.
When people asked if it was the measurement that was being changed, the answer was no, just the precision and accuracy that we can replicate the measurement.
Same goes here, the sea-level weight of 1 kg of mass is not being changed, just its precision and accuracy.
Re:Standard kilogram (Score:2)
So, define the energy of a photon from the above caesium clock and you've then defined the kilogram.
...or am I missing something?
Re:Standard kilogram (Score:2)
The whole point. (Score:3, Insightful)
Global Engineering can eat me (Score:2)
They get rich selling the public its own property.
They can go pound sand.
--Blair
"NIST, on the other hand, is a national treasure."
Re:standards (Score:1)
Re:standards (Score:2)
Tis no flamebait (Tis a remorseless eating machine)
Slugs? bwah ha ha! (Score:2)
Gimme SI any day!
And Taco, WTF is the "postersubj compression filter?" Why can't you just explain in plain English what the fuck you do or do not like in the comment boxes?
Re:standards (Score:2)
G=f(m,M)
M!=f(G)
Therefore, mass doesn't need to have anything to do with gravity, but gravity cannot exist without mass.
Furthermore, you cannot realistical measure the mass of earth at any given time to the precision required by any lucid standards committee (especially when you using that value without a standard measure of mass to begin with), nor can you realistical the distances between object centres.
Re:What??? (Score:2)
to a high degree is that they've been adjusted
to match the a weight that's been adjusted to
match a weight that's been adjusted to match the
standard kilogram... Or something like that - I don't remember how many intermediaries would be
between the standard kilogram and a commercial
weight.
Anyway, the "standard techniques" for determining
the mass involves the standard kilogram at some
point (even for the US, as the US officially defines all it's measurements using SI units).
Re:Say again? (Score:2)
Re:Comparing with what? (Score:2)
Re:Why use gravity at all? (Score:2)
though your second example (the vacuum) makes slightly more sense, it still relies on gravity, which is just slightly variable enough that it's going to be a different measurement every time.
so, back to where we started...
Re:Defining the kg with light! (Score:2)
making the actual measure of a kilogram's worth of energy, tho, would be quite messy and would likely result in the destruction of the testing apparatus, as well as the planet upon which it sat.
Re:Atom based mass standard (Score:2)
Let's see. 6.022 x 10^23 Carbon-12 atoms (approximately) to 12 grams, so about 5.018 x 10^25 Carbon-12 atoms to a kilogram. Start counting, and don't let me catch you letting a couple Carbon 14 atoms slip in!
We could easily define the kilogram by the number of Carbon-12 atoms it should contain, but then it would be a real pain to figure out if something weighed a kilogram to any great degree of accuracy.