Isotopic homogeneity of “AVO28” silicon crystal experimentally confirmed

Improved measurements of the molar mass of the AVO28 silicon single crystal, which exhibits a high enrichment regarding the ²⁸Si isotope of x(²⁸Si) > 0.9999 mol/mol, were performed by PTB Working Group 3.11 with the goal of quantifying possible local variations of the molar mass. Due to their relevance in connection with the planned redefinition of the SI units “kilogram” and “mole” (as based on fundamental constants such as the Avogadro constant, N_A), a total of 14 individual samples were investigated from 3 axial positions, each of which had 4 to 5 adjacent radial positions (Fig. 1). In addition to M(Si), the amount-of-substance fractions x(ⁱSi) of the individual isotopes ²⁸Si, ²⁹Si and ³⁰Si were also determined. Various experimental improvements, together with an optimized evaluation, made it possible to reduce the measurement uncertainties for the results of an individual sample to a level previously unmatched; as a result, possible local inhomogeneities of the isotopic pattern can be resolved.

The mean molar mass across all 14 samples is M(Si) = 27.976 970 13(12) g/mol with a relative combined uncertainty of u_c,rel(M) = 4.4 · 10^–9 (Fig. 2). This result agrees well with results published previously by PTB and confirmed by NIST (National Institute of Standards and Technology, USA) and NMIJ (National Metrology Institute of Japan). Within the measurement uncertainties, no significant variation of the molar mass or of the amount-ofsubstance fractions of the ²⁸Si and ²⁹Si isotopes was found as a function of the location in the AVO28 crystal. For the ³⁰Si isotope, minimal variations were observed just above the measurement uncertainty. Current experiments are investigating the extent to which this actually represents a property of the crystal or whether it should be attributed to experimental shortcomings.

In sum, this means that the isotopic homogeneity of the AVO28 crystal is more than sufficient for the determination of the molar mass with a relative measurement uncertainty of < 5 · 10^–9, and thus for the redefinition of the Avogadro constant.