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DOI: 10.1039/A701957B (Paper) Reference Section for: Anal. Commun., 1997, 34, 171-173

Substantial Relief From Oxygen Isotope-related Isobaric Interference in Negative Thermal Ionization Mass Spectrometry

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Yongzhong Liu, Akimasa Masdua and Masao Inoue

Abstract

A negative thermal ionization mass spectrometry (NTIMS) technique using 16O-enriched oxygen is reported, which could overcome the main drawback of NTIMS related to the oxide isobaric interference in isotope ratio determination. To remove the natural oxygen residing in the ion source, the ion source and the oxygen reservoir of the oxygen bleeding system were evacuated to an ultimate vacuum of 8 × 10-9 mbar before the highly 16O-enriched oxygen (99.99%) was introduced. The OsO3- ion was measured by NTIMS under the 16O2 partial pressure of 2 × 10-6 mbar to examine oxygen isotope composition in the OsO3- ion. It was observed that the intensities of isobaric interference Os16O217O- and Os16O218O- are notably reduced by factors of 6 and 77 times, respectively, which correspond to a maximum 7.2 × 10-16 A if the ion intensity of 192Os16O3- is 1 × 10-11 A. The results show that the oxide isobaric interferences caused by 17O and 18O can be virtually eliminated and the technique seems very promising for isotope ratio measurement of Os and other elements by NTIMS in geochemistry and cosmochemistry research.

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