Kilogram Gets Controversial; Why Not Split the Difference?

gbrumfiel writes "As Slashdot has noted, the kilogram has a problem. The SI unit is officially defined as the weight of a 130-year-old platinum-iridium cylinder in France. But the physical object appears to be getting lighter. Scientists want to replace the cylinder with a new standard based on Planck's constant, but two experiments designed to facilitate the switch keep coming up with different results. Now one researcher is proposing a solution: just average the two diverging experiments and use that value as the official definition. Not everyone thinks that averaging the two amounts to sound research: 'Deciding to just average these two results would be perfectly proper mathematics, but it would not be science,' says Michael Hart, a physicist at the University of Manchester, UK."

Impossible

[camperdave]

The physical object cannot get lighter (less massive). By definition is 1kg no matter how much mass it has. The obvious conclusion is that the rest of the universe is getting heavier.

Re:Impossible

[XanC]

Such a definition is ultimately circular. The volume of water depends on pressure, which itself has a mass component.

Re:Impossible

[mike260]

I think the GP's point was that even if you chopped a sizeable chunk off it, it would still weigh precisely 1kg. It logically follows that the universe's weight, expressed in kg, would suddenly jump upwards by a very large amount.

Re:Impossible

[mysidia]

The physical object cannot get lighter (less massive). By definition is 1kg no matter how much mass it has.

Actually... it can get lighter. Earth's gravitational field can get weaker as matter from earth is ejected or evaporates into space.

It can also get lighter as Earth's atmosphere gets heavier, making it more buoyant in earth's atmosphere.

That has nothing to do with how much mass the cylinder has, because MASS is not a measure of weight.

Mass and weight are independent. Weight is due to forces applied to mass inside a gravitational field; if the field weakens or other forces are applied to the mass inside the field, the weight will decrease or increase without any change of mass.

Earth's gravitational field and atmosphere is also not uniform, so there are places (or altitudes) you can bring the same object to, and it will be lighter or heavier, with its amount of mass being the same.

Re:Impossible

[Binestar]

And what happens to water in a vacuum?

It gets the bag wet.

Re:Impossible

[dave420]

Even if you took a massive chunk out of it with a hammer, it would still be the 1kg reference, and will still be 1kg. That's the joke :)

Re:Impossible

[hairyfeet]

It just shows yet again America was right, and y'all should have listened to the good old US of frickin A and stuck with feet, pounds, and gallons like the good Lord intended! I mean y'all are listening to cheese eating surrender monkeys, didn't that give ya a clue?

Now y'all say you're sorry, and we'll be happy to generously send y'all a proper ruler along with a pound of the finest depleted uranium rounds, made right here in the USA by the finest craftsmen, and if someone don't like your measuring you can just pop one of those bad boys in the chamber and you'd be surprised how quick them pesky arguments go your way! I mean using platinum/iridium mix, bah! DU all the way baby!

Reminds me of the deer that got away

[paiute]

A physicist, engineer and a statistician are out hunting. Suddenly, a deer appears 50 yards away.

The physicist does some basic ballistic calculations, assuming a vacuum, lifts his rifle to a specific angle, and shoots. The bullet lands 5 yards short.

The engineer adds a fudge factor for air resistance, lifts his rifle slightly higher, and shoots. The bullet lands 5 yards long.

The statistician yells "We got him!"

Re:Reminds me of the deer that got away

[140Mandak262Jamuna]

The statistician is right. Because if the deer has not moved between the first and the second shot, it is already dead. QED.

Re:Reminds me of the deer that got away

[ghmh]

Not necessarily - everything is relative. For example, you have to also look at it from the deers frame of reference:

A deer is wandering through the forest. Suddenly, a physicist, engineer and a statistician appears 50 yards away holding guns.

The deer looks at them carefully and thinks - a physicist, an engineer and a statistician: I'd best just stand still.

Bread not working?

[Sobieski]

Let them eat pounds!

How it gets lighter

[SuperKendall]

It turns out that France imposed a Mass Tax in the last few years which means the cylinder has to cough it up for the good of the state.

On the plus (or more like the non-plus) side, the people of France are now looking fit & trim.

Re:How it gets lighter

[JustOK]

So, the French govt had to run a weigh?

Well, duh.

[Black+Parrot]

Why don't they just take the weight of a gram and multiply it by 1024?

Re:Well, duh.

[arthur.gunn]

I think that would be a kibigram.

Re:Well, duh.

[formfeed]

I think that would be a kibigram.

Don't let the industry fool you. They introduced that distinction so they can put less in a box and still sell it to you as 1kg of Mac and Cheese.

This is why science is so hard

[fermion]

Science, and teaching science, is hard because it is often difficult to determine which are the truly salient facts, and what background is necessary.

In this case the background is that the standard for mass, unlike time or distance, cannot independently be constructed in the lab. This means that science and industry are susceptible to two issues. The first is degradation of a physical standard, in this case a hunk of metal in France. The second is that one is dependent on other to create proxies of the standard, and as a result have no true assurance of the accuracy of the standard. A suitable lab with suitable personal can masure time and distance without the need of a proxy manufactured by others, and no dependence on a fixed physical object.. There is a desire for the same to be true for mass.

Second, no one knows if the hunk of metal is shrinking, and if it is how much it is shrinking by. If the experts knew it was shrinking, then they could figure out how to at least partially correct it. The hunk of metal might not be charging at all, or it could be accreating matter. Without an independent standard, which does not apparently exists, as everything is based on the hunk of metal, all there is is guesswork.

The third is the idea that Planck's Constant is being used to create the standard. In fact Planck's constant is one two approaches. The other is to create a sphere from a silicon and use Avagadro's Constant to define the mass. The problem is that these two approaches do no lead to consistant results, with an error about an order of magnitude large than the expected error.

The issue with averaging is that while one does average within a result, and even results that are taken from similar procedures, it is unclear that averages in this case is suitable. It seems to me that the results point to an interesting area of research, and rather than just averaging, more work should be done understanding the inconsistency. If it is not random error, and not an artifact, then something really fascinating might be going on.

Re:Does it matter?

[drolli]

Speaking as an experimental physiscist

ahem. 175parts per billion is 1.75e-7. For metrology that is a huge discrepancy. What is worse is that the measurements themself are a factor of 5 better, leaving no room for error.

For experiments where the physicists believe they understand them this is unacceptable, because it actually means the pysics of at least one method of both is not well enough understood, i.e. you have a systematic error. If the physics is not well understood then you don't know if the systematic error will be constant.

If the measurement will not be constant then the average will also not be constant. So an metrology institute where a reference weight should be define will need both methods and still not get any stable definition.

If you already need to afford both methods, then you can create reference weights and at the same time check if the difference between both methods is the right one and constant at your place.

Important rule in experimental physics: NEVER average over systematic mistakes. Average over random results. On systematic mistakes, the word average makes no sense

Re:Can't the kilogram be derived from other SI uni

[norpy]

A gram is not the mass of 1 cubic centimeter of water. It is 1/1000 of the weight of that lump of metal in france!

There are a ton of posts above arguing over that, and you can't use that to define mass because it is affected by pressure. Pressure has a mass component so it ultimately becomes circular.

They call that math?

[martin-boundary]

Pff, that's not math.

Math is: When there's this room... with only one person in it... and then two people leave that room... now you have to wait until another person goes back in before it's actually empty.

Re:Metric System

[Michael+Woodhams]

I'm not at all sure you are serious, but enough people seriously hold this opinion that it is worth responding.

A good system of units needs:
1) Base units which are well defined and independently reconstructible (i.e. a suitably equipped lab can calibrate their equipment purely from the definition of the units.)
2) Logically constructed compound units (e.g. units of force are derived from the units of mass, time and distance.)
3) Logically constructed convenience units (e.g. kilometres for use for distances which would be an inconveniently large number of metres.)
4) To be widely used.

The initial choice of your base units is largely arbitrary - whether it was a from a not-very-accurate measure of a king's foot size or from a not-very-accurate measure of the Earth's circumference. Item (1) can be satisfied equally well (or, in the case of mass, badly) by the metric or imperial systems. The definition of the metre has long since changed from the size of the Earth to quantities measurable in a lab (as has the definition of the foot.)

The SI system (based on metric measures) beats the imperial system hands down on items 2 and 3, and because of this now has a large advantage also on item 4.

Item 2: In Imperial you might measure (heat) energy in BTU and mechanical energy in some mixture of foot-pounds-seconds, but then you need a conversion factor to compare the two. Such conversion factors are never needed in SI.

Item 3: Imperial also messes up the convenience units by having lots of weird conversion factors (e.g. an acre is (I think) a furlong by a chain. How many square feet is that? How many ounces in a ton?*) Metric uses convenience units constructed from base units via consistently named factors of 10 or 1000.

You can't use the current problems with the kilogram as a reason to prefer imperial to metric, as imperial will be just as prone to exactly the same problems. The (UK) Imperial pound is similarly defined by the mass of a unique artifact. In the US, it is defined relative to the kilogram. Mass is the last base unit which doesn't satisfy requirement (1), and the efforts to fix this are what has triggered this entire debate.

One could go a step further, and define your fundamental units in terms of fundamental physical constants (i.e. the Plank mass, Plank time and Plank distance, charge on an electron, etc.) In such a system of units, the speed of light is 1, the formula for the energy of a photon doesn't need a constant in it etc. In practice, we can't use such a system, because we can't measure (in particular) the universal gravitational constant G with sufficient accuracy. Every time we got a better measure of G, our entire system of units would need to be updated. (I.e. with current technology, this system can't satisfy requirement (1) above.)

* And how many different sorts of ounces and tons are there? It is quite a few.