The impact of MC-ICP-MS plasma conditions on the accuracy and precision of stable isotope measurements evaluated for barium isotopes.

Yu, Yang, Siebert, Christopher, Fietzke, Jan , Goepfert, Tyler, Hathorne, Ed , Cao, Zhimian and Frank, Martin (2020) The impact of MC-ICP-MS plasma conditions on the accuracy and precision of stable isotope measurements evaluated for barium isotopes. Chemical Geology, 549 . Art.Nr. 119697. DOI 10.1016/j.chemgeo.2020.119697.

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Supplementary data:

Abstract

Highlights

• Improved understanding of the behaviour of instrumental mass fractionation (IMF).
• The effect of matrix elements on IMF is largely associated with plasma conditions that can be quantified with the NAI.
• Matrix effects can be systematically and significantly attenuated by tuning of instrumental operating parameters.
• A matrix tolerance plasma state is defined for stable barium isotope analysis.
• The suggested analytical protocol is expected to be applicable to other stable isotope measurements with MC-ICP-MS.

Abstract

Stable barium isotope measurements with multi-collector inductively coupled plasma mass spectrometry (MC-ICP-MS) remain an analytical challenge and can be considerably affected by the presence of matrix elements, even when applying double spiking. Therefore significant efforts were invested in previous studies to develop efficient barium purification methods. However, due to the high variability in matrix/barium ratios for diverse sample matrices, potential matrix effects can still not be excluded. While a lot of effort has been invested into improving the chemical separation protocols, the impact of plasma conditions on the accuracy and precision of stable isotope measurements has rarely been considered. Here we present a systematic investigation of the relationship between plasma conditions, instrumental mass fractionation (IMF) and impurity (i.e. matrix) concentrations. The Normalised Ar Index (NAI) and Matrix-Ar Index (MA) are used to quantify MC-ICP-MS plasma conditions and plasma mass loading, respectively. Our results show that the effect of matrix elements on IMF is largely linked to plasma conditions (i.e. NAI) and behaves as a linear function of mass loading (i.e. MA). Accordingly, the matrix effects can be significantly attenuated by increasing the NAI thereby minimising the risk of plasma “over-loading”. The improved understanding of the behaviour of the matrix-induced IMF allows us to define a matrix tolerance plasma state for barium isotope analysis. The accuracy of this recommended method is further assessed by analyses of two well-studied reference materials, the GEOTRACES seawater reference sample SAFe D2 and the carbonate reference material JCp-1. We expect that the analytical protocol described in this study is applicable not only to barium isotope analysis, but also to a wide range of other stable isotope measurements with MC-ICP-MS.

Document Type: Article
Keywords: Barium isotopes, Plasma conditions, Matrix effects, Instrumental mass fractionation, MC-ICP-MS
Research affiliation: OceanRep > GEOMAR > FB2 Marine Biogeochemistry > FB2-MG Marine Geosystems
OceanRep > GEOMAR > FB1 Ocean Circulation and Climate Dynamics > FB1-P-OZ Paleo-Oceanography
OceanRep > GEOMAR > FB4 Dynamics of the Ocean Floor > FB4-MUHS
Refereed: Yes
Open Access Journal?: No
Publisher: Elsevier
Projects: CATS
Date Deposited: 16 Jun 2020 12:04
Last Modified: 08 Feb 2023 09:38
URI: https://oceanrep.geomar.de/id/eprint/49865

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