Accurate correction for the matrix interference on laser ablation MC-ICPMS boron isotope measurements in CaCO3 and silicate matrices
Accurate correction for the matrix interference on laser ablation MC-ICPMS boron isotope measurements in CaCO3 and silicate matrices
Knowledge of the boron isotopic composition of natural samples has found wide ranging application in both low and high temperature geochemistry. More recently, the development of boron isotope measurements using highly spatially-resolved analytical techniques is of interest as it is increasingly recognised that many materials are heterogeneous with respect to their boron isotopic composition, and moreover, that this heterogeneity yields valuable information about the environment of formation and/or mechanisms of crystallisation. Here, we build on a recently proposed methodology (Standish et al. [2019] Rapid Commun. Mass Spectrom.33:959) which enables precise and accurate δ11B measurement via LA-MC-ICPMS by accounting for a scattered Ca interference primarily on 10B. We propose minor modifications to this method via the use of 1013 Ω preamplifiers on the Faraday cup of the detector, more precise measurement of the Ca interference, and improved modelling of the shape of this interference correction. This yields single laser spot 2SE precision of ∼0.5‰ with a 70 μm beam (∼7 pg B), ∼1.4‰ with a 40 μm beam (∼2 pg B), and a long-term (1.5 year) intermediate precision in a marble standard with 15 μg g−1 [B] of <0.9‰ (2SD). Thus, spatially-resolved information comparable to that achievable via SIMS is possible. Moreover, we show theoretically and empirically that the inaccuracy predominantly resulting from a scattered Ca interference on 10B is also an issue for non-CaCO3 matrices, despite their typically lower [Ca]. Encouragingly, building multi-standard calibration lines to correct for this interference is also a way forward for silicate glasses, and we demonstrate accurate and precise (<0.5‰ 2SE) measurement of a basaltic glass with 3 μg g−1 [B] using a 74 μm diameter laser beam (<1 pg B). This paves the way forward for accurate and precise spatially-resolved δ11B measurement of a diverse range of sample matrices using laser ablation as a sample introduction system for MC-ICPMS instruments that are characterised by a scattered Ca interference in the region of m/z 10–11.
1607-1617
Evans, David
878c65c7-eab9-4362-896b-166e165eb94b
Gerdes, Axel
ef1fad8d-5b83-4188-ae77-4c2c044eb19f
Coenen, Douglas
51fff236-26c2-4ded-8f46-b86910f511ea
Marschall, Horst R.
88838f33-ea49-46c4-bdf9-d12e13dbabfe
Müller, Wolfgang
360a71f7-0b47-4ff3-8c32-1912d70401aa
9 June 2021
Evans, David
878c65c7-eab9-4362-896b-166e165eb94b
Gerdes, Axel
ef1fad8d-5b83-4188-ae77-4c2c044eb19f
Coenen, Douglas
51fff236-26c2-4ded-8f46-b86910f511ea
Marschall, Horst R.
88838f33-ea49-46c4-bdf9-d12e13dbabfe
Müller, Wolfgang
360a71f7-0b47-4ff3-8c32-1912d70401aa
Evans, David, Gerdes, Axel, Coenen, Douglas, Marschall, Horst R. and Müller, Wolfgang
(2021)
Accurate correction for the matrix interference on laser ablation MC-ICPMS boron isotope measurements in CaCO3 and silicate matrices.
Journal of Analytical Atomic Spectrometry, 36, .
(doi:10.1039/D1JA00073J).
Abstract
Knowledge of the boron isotopic composition of natural samples has found wide ranging application in both low and high temperature geochemistry. More recently, the development of boron isotope measurements using highly spatially-resolved analytical techniques is of interest as it is increasingly recognised that many materials are heterogeneous with respect to their boron isotopic composition, and moreover, that this heterogeneity yields valuable information about the environment of formation and/or mechanisms of crystallisation. Here, we build on a recently proposed methodology (Standish et al. [2019] Rapid Commun. Mass Spectrom.33:959) which enables precise and accurate δ11B measurement via LA-MC-ICPMS by accounting for a scattered Ca interference primarily on 10B. We propose minor modifications to this method via the use of 1013 Ω preamplifiers on the Faraday cup of the detector, more precise measurement of the Ca interference, and improved modelling of the shape of this interference correction. This yields single laser spot 2SE precision of ∼0.5‰ with a 70 μm beam (∼7 pg B), ∼1.4‰ with a 40 μm beam (∼2 pg B), and a long-term (1.5 year) intermediate precision in a marble standard with 15 μg g−1 [B] of <0.9‰ (2SD). Thus, spatially-resolved information comparable to that achievable via SIMS is possible. Moreover, we show theoretically and empirically that the inaccuracy predominantly resulting from a scattered Ca interference on 10B is also an issue for non-CaCO3 matrices, despite their typically lower [Ca]. Encouragingly, building multi-standard calibration lines to correct for this interference is also a way forward for silicate glasses, and we demonstrate accurate and precise (<0.5‰ 2SE) measurement of a basaltic glass with 3 μg g−1 [B] using a 74 μm diameter laser beam (<1 pg B). This paves the way forward for accurate and precise spatially-resolved δ11B measurement of a diverse range of sample matrices using laser ablation as a sample introduction system for MC-ICPMS instruments that are characterised by a scattered Ca interference in the region of m/z 10–11.
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Published date: 9 June 2021
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Local EPrints ID: 502464
URI: http://eprints.soton.ac.uk/id/eprint/502464
ISSN: 0267-9477
PURE UUID: 7a8b2f24-0d7e-4ea3-98b6-f89ab9dea31e
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Date deposited: 26 Jun 2025 17:07
Last modified: 27 Jun 2025 02:09
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Author:
David Evans
Author:
Axel Gerdes
Author:
Douglas Coenen
Author:
Horst R. Marschall
Author:
Wolfgang Müller
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