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10 Atomic Weights to Change
Dec 2010
RESTON, Va., Dec. 20, 2010 — For the first time in history, a change will be made to the atomic weights of some elements listed on the periodic table of the elements and on inside covers of chemistry textbooks worldwide.

The International Union of Pure and Applied Chemistry’s (IUPAC) Commission on Isotopic Abundances and Atomic Weights is publishing a new table that will express atomic weights of 10 elements as intervals, rather than as single standard values. The new table is the result of cooperative research supported by the US Geological Survey, IUPAC, and by other contributing commission members and institutions.

Standard atomic weights commonly are thought of as constants of nature, despite the fact that atomic weights of many common chemical elements show variations as a result of physical, chemical and biological processes.

“For more than a century and a half, many were taught to use standard atomic weights – a single value – found on the inside cover of chemistry textbooks and on the periodic table of the elements,” said Ty Coplen, director of the USGS Reston Stable Isotope Laboratory. “Though this change offers significant benefits in the understanding of chemistry, one can imagine the challenge now to educators and students, who will have to select a single value out of an interval when doing chemistry calculations.”

The standard atomic weights for hydrogen, lithium, boron, carbon, nitrogen, oxygen, silicon, sulfur, chlorine and thallium previously were expressed as central values with uncertainties that reflected natural atomic-weight variations. The weights of these elements now will be expressed as intervals to more accurately convey this variation in atomic weight. For example, boron is commonly known to have a standard atomic weight of 10.811. However, its actual atomic weight can be anywhere between 10.806 and 10.821, depending on where the element is found.

The atomic weight of an element depends upon how many stable isotopes it has and on the relative amount of each stable isotope. Isotopes are atoms of the same element that have different masses. Variations in atomic weight occur when an element has two or more naturally occurring stable isotopes that vary in abundance.

Modern analytical techniques can measure the atomic weight of many elements precisely, and these small variations in an element’s atomic weight are important in research and industry. For example, precise measurements of the abundances of isotopes of carbon can be used to determine purity and source of food products, such as vanilla and honey. Isotopic measurements of nitrogen, chlorine and other elements are used for tracing pollutants in streams and groundwater. In sports-doping investigations, performance-enhancing testosterone can be identified in the human body because the atomic weight of carbon in natural human testosterone is higher than that in pharmaceutical testosterone.

Elements with only one stable isotope do not exhibit variations in their atomic weights. For example, the standard atomic weights for fluorine, aluminum, sodium and gold are constant, and their values are known to better than six decimal places.

The USGS has a long history of research in determining atomic weights of the chemical elements. As far back as 1882, Frank W. Clark, chief chemist of the USGS, prepared a table of atomic weights.

The year 2011 has been designated as the International Year of Chemistry. The IYC is an official United Nations International Year, proclaimed at the UN as a result of the initiative of IUPAC and UNESCO. IUPAC will feature the change in the standard atomic weights table as part of associated IYC activities.

This fundamental change in the presentation of the atomic weights is based upon work between 1985 and 2010 supported by IUPAC, the USGS, and other contributing Commission members and institutions. IUPAC oversees the evaluation and dissemination of atomic-weight values.

Fundamental research underlying the changes in the atomic weight presentation for selected elements is compiled in the report “Compilation of minimum and maximum isotope ratios of selected elements in naturally occurring terrestrial materials and reagents.” An abbreviated version of this report is published in the IUPAC journal Pure and Applied Chemistry. An overview of the standard atomic weights through the 20th century is also available.

For more information, visit: 

The addition of impurities to another substance, usually solid, in a controlled manner that produces desired properties. Silicon doping with small amounts of other semimetallic elements increases the number of electrical carriers.
aluminumAmericasatomic weightBasic SciencebiologicalBiophotonicsboronBusinesscarbonchemicalChemistry InternationalchlorineCommission on Isotopic Abundances and Atomic WeightsdopingelementFluorinefoodFrank W. ClarkgroundwaterhoneyhydrogenindustryInternational Union of Pure and Applied ChemistryInternational Year of ChemistryisotopeIUPAClithiumMassnitrogenoxygenpharmaceuticalphysicalpollutantPure and Applied ChemistrypurityResearch & Technologysiliconsodium and goldsportsstablestreamsulfurTest & MeasurementtestosteronethalliumTy CoplenUNESCOUnited NationsUS Department of the InteriorUS Geological SurveyUSGSUSGS Reston Stable Isotope LaboratoryvanillaVirginia

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