The kilogram is a 127-year-old relic. It is the last remaining standard of measurement in the International System of Units that is still based on a physical object—a single, golf ball–sized cylinder of platinum and iridium that sits in a vault just outside Paris. It is kept under lock and key—and secured underneath three vacuum-sealed, glass bell jars—in a temperature-controlled room in the International Bureau of Weights and Measures. The slightest amount of dust, moisture or oil from fingerprints could alter the mass of the cylinder.* In fact, the so-called Le Grand K is so well protected that caretakers remove it only every 40 years so that other prototypes from around the world can be compared with it. Even then, it is impossible to tell if changes are caused by the fact that Le Grand K lost mass or that one of its copies gained some from contamination.
This is a serious problem for modern science, given that many technologies depend on an accurate measurement of the kilogram, says Stephan Schlamminger, a physicist at the National Institute of Standards and Technology. That is why scientists, for decades now, have wanted to redefine the kilogram in terms of constants found in nature—an achievement that would provide a more stable (and accessible) unit of measurement.
Schlamminger and his team recently reported that they have paved the way for such a feat by using Planck's constant, a mathematical value that describes the link between the energy of a photon and its frequency and that can be related to mass through Einstein's famous equation E = mc2. As detailed in the Review of Scientific Instruments, the NIST team measured Planck's constant with a high-tech scale called a watt balance.
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The researchers placed a known mass on one end of the scale and then counterbalanced it by sending an electric current through a movable coil of wire suspended in a magnetic field. They then used that electromagnetic force to measure Planck's constant down to an accuracy of 34 parts per billion.
Before the world redefines the kilogram based on Planck's constant, however, multiple teams must publish independent measurements by July 2017. At the 2018 General Conference on Weights and Measures, the data from each group will then be evaluated, including a constant calculated by counting the atoms in a silicon sphere. A complex computer program will subsequently sift through the numbers to arrive at a final value. Only then may Le Grand K be retired to the Louvre, next to the old meter and other artifacts.
By the Numbers
6.626 069 83 × 10−34 kg m2/s
Planck's constant as measured using the NIST-4 watt balance
0.000 000 22 × 10−34 kg m2/s (or 34 parts per billion)
Level of uncertainty in the measurement by Stephan Schlamminger's team
230 miles
Driving distance between Washington, D.C., and New York City
0.5 inch
Level of uncertainty in the measurement of distance that is comparable to 34 parts per billion
SOURCE: NATIONAL INSTITUTE OF STANDARDS AND TECHNOLOGY**
*Editor's Note (11/10/16): This sentence from the print article was changed after it was posted online. The orignial erroneously stated that contraction or expansion of Le Grand K cylinder can alter its mass.
**Editor's Note (9/6/16): The print article incorrectly attributed the source as the National Institutes of Health. The error was corrected after it was posted online.
A brief history of the international system of units
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