Exactly One Kilogram Of Silicon

Ed Pegg Jr writes "You may know of the importance of 299792458 for length, and 9192631770 for time. However, the official standard for weight is still a block of platinum/iridium made a hundred years ago. A group of scientists from the Avogadro Project are hoping to change that, though, by producing a perfect sphere of ultrapure silicon."

A perfect sphere?

[ptaff]

A perfect sphere would imply fractional quarks and fractional parts of quarks, and ... an infinite precision!

Pi is still irrational, isn't it?

Don't tell me the all my math teachers lied to me!

Re:A perfect sphere?

[sporty]

A perfect sphere would imply fractional quarks and fractional parts of quarks, and ... an infinite precision!

Pi is still irrational, isn't it?

And worrying on the quark level might make you a little irrational too ;) There's always room for error...er.. jello.

Honest Question

What exactly is the benefit of having an object with a mass of exactly one kilogram if we already know, mathematically, how much one kilogram is?

Re:Honest Question

[qengho]

What exactly is the benefit of having an object with a mass of exactly one kilogram

To calibrate scales.

Re:Honest Question

[Istealmymusic]

Yes.

Re:Honest Question

How do they keep the perfect sphere from rolling off the scale?

Old news

[L.+VeGas]

producing a perfect sphere of ultrapure silicon

Pam Anderson has already cornered this market.
Ohhhh, silicon...

Stick it to the French

[An.+(Coward)]

We'll come up with our own standard of mass, and we'll call it the Freedom Sphere. So put that in your pipe and smoke it, Jacques Chirac! With your burned lips!

why kilogram?

the SI unit for length is the metre - not the kilometre

why is the unit for mass the kilogram when it should more logically be the gram?

using the gram might be easier to accurately measure too.

Re:why kilogram?

Neither system is consistent in the sense I suspect the original poster meant. Both systems mix purportedly "basic" units with a different sort of unit that requires a prefix, despite the fact that it's supposed to be basic:

centimeter - gram - second
meter - kilogram - second

It's just a matter of names. Logically, either system should be all "basic" units, with no prefixes. If a meter happened to be defined as 1/100th the current length, then you'd have the "meter gram second" system for the first case, and it would make more sense.

Of course, you still have the problem that a kilo of water is a cubic decimeter, not a cubic meter. So in the MKS system, you'd have to have a "gram" weighing rather inconveniently 1000 times as much, and a meter 1/10th the size, to make this "meter gram second" system more consistent.

The real answer, of course, lies in that word "convenient". The metric system, despite the claims of some proponents, is not really particularly inherently logical. Sure, it uses powers of ten. But the units themselves were chosen completely arbitrarily. And they were chosen simply to be relatively close to units already in use at the time - yards, bushels, pounds, quarts, and so on, because those were convenient sizes people were used to, not because there was some overriding scientific reason for choosing those sizes. (1/10^7 of the distance from Paris to the North Pole, indeed. Talk about chauvinisitic... as if there were a fundamental scientific principle rooted in the location of Paris!)

A truly "scientific" system would have units sized on fundamental constants - speed of light, Planck's constant, permitivity/permissivity of free space, all those sorts of numbers. You'd know you had such a system because they would be nice round numbers rather than arbitary long strings of digits as they are in the current metric (or English) system.

And when it comes to prefixes, you could always argue that the English system is far more logical in the age of computers. The metric system goes by powers of ten, which happens to be convenient for manual calculation. But the English system goes by powers of two; e.g, 16 cups = 8 pints = 4 quarts = 2 half gallon = 1 gallon. Much nicer for computers; no roundoff error there in the floating point processor, and you can change units by a simple shift operation rather than the hugely more time-consuming multiplication by ten. Same logic, different base.

Re:why kilogram?

[david+duncan+scott]

There is a system based on fundamental constants, the Planck Units.

Still, just try getting a .75 centipace wrench. You can't even order them, and without that, just how the hell are you supposed to repair the flux capacitor?

BILLY!

[teamhasnoi]

How many times have I told you NOT to play with your perfect sphere of ultrapure silicon outside the house! It's the official standard of weight and here YOU are rolling it through a SANDBOX! No telling how many nanograms of mass you've abraded off of it!

Get in here this INSTANT, and bring it with you! When your father gets home you are going to be grounded, young man! Two weeks to the PICOSECOND by the atomic clock in the kitchen. Now go stand in the corner, and NO LEANING! You'll probably throw the wall out of plumb, or expand the angle to 90.7632+1E degrees or something, you troublemaker!

To Mr. Pegg

[Captain+Nitpick]

However, the official standard for weight is still a block of platinum/iridium made a hundred years ago.

ITYM mass. SI has no unit for weight. There's the newton for force, but it is not defined in terms of gravity. It is also not a SI base unit.

New Austin Powers movie plot.

I've always have this strange idea of a Austin Powers movie where DR EVIL has stolen the "Kilogram" and held the entire world hostage for one trillion pesos.

What an idea.

meter nit

[yerricde]

1/10^7 of the distance from Paris to the North Pole,

Actually, the meter was defined as roughly 1e-7 of the distance from the equator to the North Pole along Paris's meridian, making the earth roughly 4e7 m (40,000 km) around.

Did anyone else think of...

[AEton]

It's the new, improved, Happy Fun Silicon Ball!
Warning: Pregnant women, the elderly and children under 10 should avoid prolonged exposure to Happy Fun Silicon Ball.
Discontinue use of Happy Fun Silicon Ball if any of the following occurs:

• Chipping
• Scratching
• Spontaneous degeneration
• Conversion from matter to energy (E = mc^2 = c^2 energy!)
• Sudden change in mass of everything around you

Happy Fun Silicon Ball has been shipped to our troops in Kuwait and is also being dropped by our warplanes on Iraq. Our Westernization process of SI imperialism will defeat them!
When not in use, Happy Fun Silicon Ball should be returned to its special container and kept under refrigeration...
Do not taunt Happy Fun Silicon Ball.

Happy Fun Silicon Ball
Accept no substitutes!

Re:Why does it have to be a SPHERE?

[sarabob]

as TFA says, it's to avoid having edges which can be chipped etc.

Okay, you asked for it

[Noren]

A kilogram is a unit of mass and a liter is a unit of volume. (You probably knew that...)

Water expands and contracts as the temperature and pressure around it change, even in the range where it is still liquid.

It turns out that liquid water at 1 atmosphere pressure is most dense at about 4 degrees Centigrade, where its density is 0.9999750 g/cm^3. at closer to room temperature- at 22 degrees C- its density is only .9977735 g/cm^3. It never actually gets up to 1 g/cm^3 the unit system was originally designed to use, I think because of the limits of accuracy of measurements when the current definitions of individual units were set. In defining a unit, all those significant figures are relevant, so for these purposes the above are unacceptably big differences.

Measuring mass by what the volume of water is would be more complicated and less accurate than the current system. Besides, a liter is trickier to define than a kilogram, so it'd likely be the other way around if defined in terms of each other.

that won't help much

[u19925]

the problem of mass standard is not that it was made 100 years ago. the problem is that there is no way to describe it so that it can be reproduced independently. as one of the famous scientist said, "we can communicate our definition of length and time to aliens 1000 light years away (if they are listening us), but we can't tell them what we mean by 1 kilo".

Secondly, it doesn't matter either what exactly is 1 kilogram. what matters is some reference atomic mass and then pick up Avogadro number (based on existing 1 kilo mass) and then get rid of the existing standard. this would allow independent reproduction (e.g. 1 kg is equivalent of 6.02...... x 10^23 atoms of Oxygen 16 in certain energy state. this scheme too has problem. there is no practical way of verifying that you have met the standard definition. so, two scientists can argue that each is possesing exact 1 kg and this cannot be arbitrated.

Re:Diamond

[SEE]

Not only do diamonds' surfaces oxidize, they're pretty easy to burn, and only metastable in any case.

Diamonds are *not* forever.

Mathematics != Real World

[aricusmaximus]

A good question. The reason is that a kilogram is not a mathematical object (which is pure idea). It is a scientific object (which can and should have a real world representation).

Pi does not exist in the real world. If you don't agree, show me an object in the real world that has exactly pi length, weight, or volume.

By contrast, the kilogram is an idea (an agreement really), that leads to a real world object (bar of platinum, sphere of silicon) that people can test their measuring devices against.

Ask yourself this: if you and your friend had two scales, how would you know which one is more accurate?

Answer: you would test them against a scale you agreed was more accurate.

But, in order to test for accuracy, you need a very "accurate" object. You need something that everyone agrees weighs a certain amount (say a kilogram?) And your "most accurate" scale had better exactly weigh that object as exactly one kilogram.

That's basically what calibration is: you take an object you declare to be 1 kg (or 1 g) and then you set your scale to indicate it as such. Obviously, there is more to it than that, but that's the very basics.

Science relies tremendously on these types of standards. One of the biggest (and unsung) "wins" of the 20th century was the tremendous increase in the objective standards of accuracy. Imagine trying to build a microprocessor if everything was designed in terms of hand lengths or feet lengths of the various contractors. Without increasingly tight, objective standards of measurement, modern science and technology would not exist.

Ironically enough, I'm a mathematician. I would encourage you to talk to a professional scientist or engineer and ask them about it.