Peter Fuchs scite author profile

This paper concerns an international research project aimed at determining the Avogadro constant by counting the atoms in an isotopically enriched silicon crystal. The counting procedure was based on the measurement of the molar volume and the volume of an atom in two 1 kg crystal spheres. The novelty was the use of isotope dilution mass spectrometry as a new and very accurate method for the determination of the molar mass of enriched silicon. Because of an unexpected metallic contamination of the sphere surfaces, the relative measurement uncertainty, 3 × 10−8 NA, is larger by a factor 1.5 than that targeted. The measured value of the Avogadro constant, NA = 6.022 140 82(18) × 1023 mol−1, is the most accurate input datum for the kilogram redefinition and differs by 16 × 10−8 NA from the CODATA 2006 adjusted value. This value is midway between the NIST and NPL watt-balance values.

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Determination of the Avogadro Constant by Counting the Atoms in aSi28Crystal

Andreas¹,

Azuma²,

Bartl³

et al. 2011

Phys. Rev. Lett.

203

190

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The Avogadro constant links the atomic and the macroscopic properties of matter. Since the molar Planck constant is well known via the measurement of the Rydberg constant, it is also closely related to the Planck constant. In addition, its accurate determination is of paramount importance for a definition of the kilogram in terms of a fundamental constant. We describe a new approach for its determination by counting the atoms in 1 kg single-crystal spheres, which are highly enriched with the 28Si isotope. It enabled isotope dilution mass spectroscopy to determine the molar mass of the silicon crystal with unprecedented accuracy. The value obtained, NA = 6.022,140,78(18) × 10(23) mol(-1), is the most accurate input datum for a new definition of the kilogram.

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Surface layer determination for the Si spheres of the Avogadro project

et al. 2011

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For the accurate determination of the Avogadro constant, two 28Si spheres were produced, whose macroscopic density, in addition to other values, must be determined. To make a contribution to the new definition of the kilogram, a relative standard uncertainty of less than 2 × 10−8 has to be achieved. Each silicon surface is covered by a surface layer (SL). Consequently, correction parameters for the SL are determined to be applied to the mass and volume determination of the enriched spheres. With the use of a large set of surface analysing techniques, the structure of the SL is investigated. An unexpected metallic contamination existing on the sphere surface enlarges the uncertainty contribution of the correction parameters above the originally targeted value of 1 × 10−8. In the framework of this investigation this new obstacle is resolved in two ways. A new combination of analytical methods is applied to measure the SL mass mSL and the thickness dSL, including this new contamination, with an uncertainty of u(mSL) = 14.5 µg and 14.4 µg, respectively, and u(dSL) = 0.33 nm and 0.32 nm for the 28Si spheres AVO28-S5 and AVO28-S8, respectively.In the second part of the work, the chemical composition of these metallic contaminations is found to be Cu, Ni and Zn silicide compounds. For the removal of this contamination, a special procedure is developed, tested and applied to the spheres to produce the originally expected surface structure on the spheres. After the application of this new procedure the use of x-ray reflectometry directly at the spheres will be possible. It is expected to reduce the uncertainty contribution due to the SL down to 1 × 10−8.

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Low-pressure plasma cleaning of Au and PtIr noble metal surfaces

Fuchs

2009

Applied Surface Science

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New instrument for the study of ‘the kg, mise en pratique’: first results on the correlation between the change in mass and surface chemical state

Fuchs¹,

Marti²,

Russi³

2012

Metrologia

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In order to study the practical means of a dissemination of the redefined kilogram, the mass laboratory of METAS has built a new and unique instrument, which combines high precision mass measurement and element-specific surface chemical analysis by x-ray photoelectron spectroscopy (XPS) under identical conditions. It is especially designed for the analysis of large samples such as real 1 kg standards and artefacts of up to 100 mm in diameter. In this paper, we first provide a detailed description of the apparatus. In a second step we demonstrate its performance by applying various processes, such as the transfer from ambient to vacuum, cleaning by low-pressure hydrogen plasma, transfer from vacuum to ambient and recontamination in air with time. Real 1 kg PtIr standards and surface artefacts have been monitored at individual steps gravimetrically, and in vacuum additionally by XPS. Values for the gain and loss of mass due to the application of different processes are provided. A model for the short-term recontamination after cleaning is presented, showing the initial growth of contaminants is self-limited.

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Peter Fuchs

Counting the atoms in a²⁸Si crystal for a new kilogram definition

Determination of the Avogadro Constant by Counting the Atoms in aSi28Crystal

Surface layer determination for the Si spheres of the Avogadro project

Low-pressure plasma cleaning of Au and PtIr noble metal surfaces

New instrument for the study of ‘the kg, mise en pratique’: first results on the correlation between the change in mass and surface chemical state

Contact Info

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Peter Fuchs

Counting the atoms in a28Si crystal for a new kilogram definition

Determination of the Avogadro Constant by Counting the Atoms in aSi28Crystal

Surface layer determination for the Si spheres of the Avogadro project

Low-pressure plasma cleaning of Au and PtIr noble metal surfaces

New instrument for the study of ‘the kg, mise en pratique’: first results on the correlation between the change in mass and surface chemical state

Contact Info

Product

Resources

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Counting the atoms in a²⁸Si crystal for a new kilogram definition