Scientists at the National Physical Laboratory (NPL) have released new research results that could affect how we measure a kilogram – the last SI unit based on a manufactured object.
The International System of Units (SI) is the foundation for all our measurements from the beer in your pint to the gap between the tick and the tock on your clock.
SI units are defined by the General Conference on Weights and Measures. The next meeting of the conference, in November 2007, will consider a range of issues related to the maintenance of the SI, including an initial proposal to prepare for the redefinition of several of the base units.
This could include redefining mass relying on a physical constant - a physical quantity that is universal in nature and constant in time - rather than the less accurate current means, a man-made object.
For 30 years scientists across the world have been looking to measure the value of a physical constant as accurately as possible using the existing man-made unit for a kilogram. Once they have achieved this the fixed value of one of these constants can be incorporated it into a new definition of the kilogram.
Research using Planck’s constant, originated at NPL employs an indirect comparison of mechanical and electrical power to measure the kilogram using length, time and quantum mechanical effects.
The National Institute of Standards and Technology (NIST) in the US have managed to measure Planck’s constant using a watt balance machine and record results with uncertainties of 36 parts in a billion. To provide a method with an uncertainty for 1kg of better than 20 parts in a billion without unresolved discrepancies would be enough to accurately redefine the kilogram if the results are mirrored in other independent experiments.
However, new research from the UK’s National Physical Laboratory (NPL) measuring Planck’s constant using its Mark 2 watt balance show a significant discrepancy with these results. As both watt balances, though different in design, are using the same principle the results should be closer together.
The value of Planck’s constant calculated from the latest NPL results is 6.62607095(44) x 1034 J s [66 x 109]. This value of Planck’s constant differs by 308 nW/W from the result published by NIST in 2007 of 6.62606891(24) x 1034 J s.
This difference is a significant discrepancy. Work on the NPL Mark II watt balance will go on to March 2008 to reduce the uncertainties of the apparatus and either confirm the NPL result or reveal the source of this discrepancy.
Seton Bennett, Deputy Director at the National Physical Laboratory said:
“Given the discrepancy in these results, further results are required before the CGPM could consider adopting a new definition for the kilogram. A decision to replace the International Prototype with a definition based on Planck’s constant requires substantially more research by laboratories across the world, building on the strong foundations already laid by the National Physical Laboratory and its international partners.”
National Physical Laboratory (NPL)
NPL is a world-leading centre of excellence in developing and applying the most accurate measurement standards.
For more than a century it has developed and maintained the nation’s primary measurement standards. These standards support an infrastructure of traceable measurement through the UK and the world that ensures accuracy and consistency.
Journal
Metrologia