A Massive Bet: The Planck Napkin
Jason Stoughton, Leader, NIST Internal Communications and Inquiries Group, NIST Public Affairs Office
So, a bunch of metrologists walk into a bar.
In late December 2013, a group of NIST researchers met at the local watering hole across the street from NIST’s Gaithersburg, Maryland, campus. NIST researchers meeting up after work during the holidays is a common occurrence, but this particular group had more on their minds than just hoisting a few pints. As it turns out, they had been working on hoisting something else.
The group had good reason to celebrate that evening. They had just achieved a major milestone in their work and were looking forward to the next phase of their research.
“I remember being at the long table on the second floor of the bar passing around this napkin,” says mechanical engineer Leon Chao.
That napkin was the beginning of a bar bet concerning a fundamental constant of the universe — a bet that would take four more years to settle.
Written on the napkin were several long strings of numbers set equal to the letter h, a symbol known well to Chao and his fellow researchers for denoting Planck’s constant. The many digits were central to the work they were celebrating: NIST’s contribution to a worldwide scientific effort to redefine exactly what a kilogram is.
Big K and little h
The International Prototype Kilogram (IPK) is a shiny cylinder of platinum and iridium. Cast more than 120 years ago, it lives a closely guarded life inside a triple-locked underground vault outside Paris. Affectionally known as Le Grand K, or Big K, this metal cylinder is the kilogram. It’s the king when it comes to measuring mass. All measurements of weight and mass in practically every country on Earth can be traced back, through national metrology institutes like NIST, to Big K.
But it’s not a perfect system. Just imagine if Big K was dropped. Or stolen. Or breathed on.
A long-term endeavor of many measurement scientists around the world is to improve the system by replacing Big K. Not with another object, but with an equation based on unchanging constants of the universe. Much like the redefinition of other basic units of measurement, such as the meter and the second, the aim is to define the standard of mass in terms of physical constants instead of a fragile, filchable object.
The linchpin for achieving this ambitious goal is determining a hyper accurate value for h, Planck’s constant, a number identified by physicist Max Planck in 1900, back when Big K was only 11 years old. Through the relationship of E=hν, Planck’s constant (h) links a single photon’s teeny tiny amount of energy (E) to its frequency (ν). By combining it with Einstein’s discovery of the equivalence of mass and energy — represented by the more famous E=mc2 — a kilogram can be precisely defined in terms of energy, rather than by a vault-dwelling metal cylinder in France.
But to truly dethrone Big K, researchers would have to determine the value of Planck’s constant to an almost unthinkable level of accuracy, equivalent to measuring the distance between New York City and Washington, D.C., down to less than 1.27 centimeters (0.5 inch). This level of accuracy would not be even remotely possible until more than a century after Planck’s discovery.
Meanwhile, back at the bar
The NIST researchers enjoying happy hour in December 2013 were celebrating their recent achievement — a newly submitted and highly accurate value of Planck’s constant, achieved using a complex instrument called a watt balance, which is now called a Kibble balance, in honor of the device’s inventor, Bryan Kibble. NIST’s watt balance program goes back many years and several generations of instruments.
The basic function of a watt balance is similar to a traditional balance scale with two pans, but with a critical difference. Where a balance scale compares two masses, a watt balance compares the weight of a mass with an electromagnetic force. In 2013, NIST was on its third-generation watt balance, NIST-3, a liquid-helium-guzzling beast of a machine that researchers kept confined to a multistory copper-lined cage.
Although NIST-3 was a high-precision instrument, the researchers at the bar knew it was not accurate enough to redefine the kilogram. To attain that level of accuracy, they would need to build a new watt balance: NIST-4. Their hope was that NIST-4 would provide the most accurate measurement yet of Planck’s constant and, when combined with research at other national metrology institutes, finally provide a new definition of the kilogram and give Big K a well-earned retirement.
So, how to commemorate this important, nay, historic, occasion? With a friendly bar bet, of course.
Anybody got a pen?
“Everyone was very excited,” recounts Frank Seifert, a NIST guest researcher. “We had just submitted our data from NIST-3 and we were looking forward to building NIST-4.”
Physicist Stephan Schlamminger was there as well. “That night we went out to the bar for happy hour,” he remembers. “Sitting around the table, it came up spontaneously. Dave (Newell, another NIST physicist) had a pen and started writing.
Each of the researchers took a crack at guessing the final value of Planck’s constant that NIST would eventually determine and submit. They were looking ahead several years into the future, to the time when Planck’s constant would be defined so accurately that it could be used, along with other physical constants, to truly redefine the kilogram.
Of course, it was also happy hour.
“I thought, ‘I’m going to win it,’” says physicist Darine Haddad. “I was sitting there drinking my beer, doing the calculation … I think I missed a nine halfway through my beer.”
The result of all this was an undetermined number of pints consumed and a napkin with 10 individual guesses for the value of h, one from each person who contributed to the work.
Now, if you’d like to examine this very mathy napkin, you’re out of luck. The researchers sealed it inside a plastic bottle and buried it that Christmas Eve in a suitable location: under about 1.82 meters (6 feet) of sand in a cavity within the massive concrete foundation of NIST-4.
And there it will remain, a permanent part of the project’s foundation both literally and figuratively, perhaps to be discovered by future metrologists.
A piece of cake
Fast-forward four years ahead to the summer of 2017. The watt balance team, using NIST-4, has now submitted yet another value for Planck’s constant, this one more accurate than any previous value determined by NIST.
So, who came the closest and won the bet? That honor goes to Shisong Li, in 2013 a guest researcher at NIST from China’s National Institute of Metrology. Li now works in France, quite near to Big K, at the International Bureau of Weights and Measures.
NIST’s newly submitted value for Planck’s constant is now being compared with values submitted from the national measurement labs of other countries. Their combined work will be used to permanently fix the value of Planck’s constant, defining it with a level of precision that likely would’ve surprised Planck himself.
And, as you might imagine, the researchers made another well-earned pilgrimage to the bar to celebrate. This time, however, they had a fancy cake to commemorate the occasion. Among the decorations on top of the cake is NIST’s final number for h, written in icing: 6.626069934 x 10^−34 kg∙m^2/s.
But it’s much more impressive when written like this:
And it was an Italian rum cake, by the way.
This post originally appeared on Taking Measure, the official blog of the National Institute of Standards and Technology (NIST) on August 25, 2017.
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About the Author
In addition to being an unabashed science fanboy, Jason Stoughton is a writer, photographer, video producer, and supervisory public affairs specialist at NIST. Before coming to NIST he worked in broadcast television and video production in a variety of roles from creative director to night shift dub room technician, somehow winning 11 Emmy awards in the process. He lives in Silver Spring, Maryland, with his wife and daughter.