A fully automated simultaneous single-stage separation of Sr, Pb, and Nd using DGA Resin for the isotopic analysis of marine sediments

Retzmann, Anika; Zimmermann, Tristan; Pröfrock, Daniel; Prohaska, Thomas; Irrgeher, Johanna

doi:10.1007/s00216-017-0468-6

Cited by 50 publications

(49 citation statements)

References 52 publications

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“…The 202 Hg beam intensity, consistently below 0.15 mV, was monitored to correct for these very low isobaric interferences of 204 Hg on 204 Pb. This correction was performed online applying equations detailed in Retzmann et al (2017) (Chauvel and Blichert-Toft 2001) were diluted to a concentration of 200 ng ml -1 Nd reaching~3 V on the 144 Nd mass. The analyses were performed in wet mode, but sample solutions as low as 10 ng ml -1 can also be measured using a dry plasma mode (Aridus, CETAC Technologies, Omaha, NE, USA).…”

Section: Isotopic Determinationsmentioning

confidence: 99%

First Multi‐Isotopic (Pb‐Nd‐Sr‐Zn‐Cu‐Fe) Characterisation of Dust Reference Materials (ATD and BCR‐723): A Multi‐Column Chromatographic Method Optimised to Trace Mineral and Anthropogenic Dust Sources

Vanderstraeten

Bonneville

Gili

et al. 2020

Geostandard Geoanalytic Res

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Atmospheric dust is an integral component of the Earth system with major implications for the climate, biosphere and public health. In this context, identifying and quantifying the provenance and the processes generating the various types of dust found in the atmosphere is paramount. Isotopic signatures of Pb, Nd, Sr, Zn, Cu and Fe are commonly used as sensitive geochemical tracers. However, their combined use is limited by the lack of (a) a dedicated chromatographic protocol to separate the six elements of interest for low-mass samples and (b) specific reference materials for dust. Indeed, our work shows that USGS rock reference materials BHVO-2, AGV-2 and G-2 are not applicable as substitute reference materials for dust. We characterised the isotopic signatures of these six elements in dust reference materials ATD and BCR-723, representatives of natural and urban environments, respectively. To achieve this, we developed a specific procedure for dust, applicable in the 4-25 mg mass range, to separate the six elements using a multi-column ion-exchange chromatographic method and MC-ICP-MS measurements.

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Section: Isotopic Determinationsmentioning

confidence: 99%

First Multi‐Isotopic (Pb‐Nd‐Sr‐Zn‐Cu‐Fe) Characterisation of Dust Reference Materials (ATD and BCR‐723): A Multi‐Column Chromatographic Method Optimised to Trace Mineral and Anthropogenic Dust Sources

Vanderstraeten

Bonneville

Gili

et al. 2020

Geostandard Geoanalytic Res

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“…Here we present a new protocol that facilitates this step through the automation of boron purification using the prepFAST‐MC (prepFAST Multi Collector, developed by Elemental Scientific, ESI, Omaha, NE, USA). This method has been used successfully for other isotopic systems measured in various materials, including Sr and Ca isotopes, 19 Cu isotopes in biological samples, 20 separation of Sr, Pb and Nd isotopes from marine sediments, 21 U and Th isotopes in corals, 22 and Nd 23 . Here for boron isotopes, we optimise the blank contribution and matrix wash‐out and test the method on a variety of standards and matrices including coral samples, seawater, and carbonate/boric acid reference materials or standards.…”

Section: Introductionmentioning

confidence: 99%

“…Here for boron isotopes, we optimise the blank contribution and matrix wash‐out and test the method on a variety of standards and matrices including coral samples, seawater, and carbonate/boric acid reference materials or standards. The reader is referred to the literature 19,21,22 and Figure S1 (supporting information) for a more complete description of the prepFAST‐MC system and schematic of the set‐up used here.…”

Section: Introductionmentioning

confidence: 99%

Automation of boron chromatographic purification for δ¹¹B analysis of coral aragonite

Vega

Foster

Martínez‐Botí

et al. 2020

Rapid Comm Mass Spectrometry

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Rationale:To detect the small changes in past pH , the boron isotope ratio of coral carbonates, expressed as the δ 11 B value, needs to be both precise and accurate (2sd <<1‰). Boron measurements by Multi-Collector Inductively Coupled Plasma Mass Spectrometry (MC-ICPMS) require the boron to be carefully purified before analysis, which is time consuming, and requires specialist training. Here, we use the prepFAST-MC method that enables the automatic extraction of B (up to 25 ng load) from a CaCO 3 matrix.Methods: Samples were purified using the prepFAST-MC automated system with ã 25-μL column of Amberlite IRA743 resin. Boron isotope measurements were performed by MC-ICPMS. The effects of matrix load, speed of sample loading onto the column, and blank contamination were tested to evaluate the effects on the purification process. The optimised protocol was tested on various standards and samples of aragonite corals. Results:The blank contribution for the approach is~60 pg and is negligible given our sample size (<0.2% sample size). Efficiency of matrix removal is demonstrated with the addition of up to 1.6 mg of dissolved low-B calcium carbonate to NIST SRM 951 with no impact on the accuracy of δ 11 B values. The Japanese Geological Survey Porites reference material JCp-1, boric acid standard NIST SRM 951, and seawater, all processed on the prepFAST-MC system, give δ 11 B values within error of literature values (δ 11 B JCp-1 = 24.31 ± 0.20‰ (2sd, n = 20); δ 11 B NIST 951 = −0.02 ± 0.15‰ (2sd, n = 13) and δ 11 B Seawater = 39.50 ± 0.06‰ (2sd, n = 2)). Results obtained from the coral Siderastrea siderea purified with the prepFAST-MC system show an average offset from the manual ion-exchange protocols of Δδ 11 B = 0.01 ± 0.28‰ (2sd, n = 12). Conclusions:Our study demonstrates the capacity of the prepFAST-MC method to generate accurate and reproducible δ 11 B values for a range of materials, without fractionation, with efficient matrix removal and with negligible blank contribution.

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“…Therefore, it is definitely a simple and time-saving method for purification of both Ca and Fe using only one column containing TODGA resin and facilitates determination of their isotope ratios in geological materials. So far, TODGA resin has proved to be sufficient to remove interfering ions from geological samples and successful measurements have been achieved for non-traditional Fe-Ca isotopes and traditional Sr-Nd-Hf-Pb isotopes (Connelly et al 2006, Pourmand and Dauphas 2010, Li et al 2016, Feng et al 2017, Retzmann et al 2017, Guan et al 2019. With combination of the non-traditional and traditional isotopes, it is very useful to widen the applicability of the TODGA resin to geological samples for the determinations of multi-elemental isotopes, particularly for precious and rare samples with less sample size, such as meteorites.…”

Section: Ca and Fe Isotope Measurement Results In Reference Materialsmentioning

confidence: 99%

Determination of δ^44/40Ca and δ^56/54Fe in Geological Materials Combined with a Simplified Method for their Separation Using a Single TODGA Resin Column

Guan¹,

Sun²,

Zhang

et al. 2020

Geostandard Geoanalytic Res

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A measurement procedure has been developed for the determination of d 44/40 Ca and d 56/54 Fe in geological samples by multi-collector inductively coupled plasma-mass spectrometry (MC-ICP-MS) and thermal ionisation mass spectrometry (TIMS), combined with a single TODGA resin column for their separation. Using the TODGA resin for separation of geological materials, Fe and Ca ions were eluted by using 8 ml of 1.5 mol l-1 HNO 3 and 8 ml of 2 mol l-1 HCl, respectively, and their recovery was 99.7 AE 0.4% (n = 3) for the former and 99.4 AE 0.6% (n = 3) for the latter after removal of matrix and interfering elements using 12 ml of 6 mol l-1 HCl. This procedure was validated by the reference materials AGV-2, BCR-2 and BHVO-2. Their Fe and Ca isotope data were comparable to their literature values, confirming a single column containing TODGA resin can be applied to the separation of Fe and Ca in geological samples for determination of their isotope ratios free of measurement bias.

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A fully automated simultaneous single-stage separation of Sr, Pb, and Nd using DGA Resin for the isotopic analysis of marine sediments

Cited by 50 publications

References 52 publications

First Multi‐Isotopic (Pb‐Nd‐Sr‐Zn‐Cu‐Fe) Characterisation of Dust Reference Materials (ATD and BCR‐723): A Multi‐Column Chromatographic Method Optimised to Trace Mineral and Anthropogenic Dust Sources

First Multi‐Isotopic (Pb‐Nd‐Sr‐Zn‐Cu‐Fe) Characterisation of Dust Reference Materials (ATD and BCR‐723): A Multi‐Column Chromatographic Method Optimised to Trace Mineral and Anthropogenic Dust Sources

Automation of boron chromatographic purification for δ¹¹B analysis of coral aragonite

Determination of δ^44/40Ca and δ^56/54Fe in Geological Materials Combined with a Simplified Method for their Separation Using a Single TODGA Resin Column

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A fully automated simultaneous single-stage separation of Sr, Pb, and Nd using DGA Resin for the isotopic analysis of marine sediments

Cited by 50 publications

References 52 publications

First Multi‐Isotopic (Pb‐Nd‐Sr‐Zn‐Cu‐Fe) Characterisation of Dust Reference Materials (ATD and BCR‐723): A Multi‐Column Chromatographic Method Optimised to Trace Mineral and Anthropogenic Dust Sources

First Multi‐Isotopic (Pb‐Nd‐Sr‐Zn‐Cu‐Fe) Characterisation of Dust Reference Materials (ATD and BCR‐723): A Multi‐Column Chromatographic Method Optimised to Trace Mineral and Anthropogenic Dust Sources

Automation of boron chromatographic purification for δ11B analysis of coral aragonite

Determination of δ44/40Ca and δ56/54Fe in Geological Materials Combined with a Simplified Method for their Separation Using a Single TODGA Resin Column

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Automation of boron chromatographic purification for δ¹¹B analysis of coral aragonite

Determination of δ^44/40Ca and δ^56/54Fe in Geological Materials Combined with a Simplified Method for their Separation Using a Single TODGA Resin Column