Coprecipitation as a One-Step Se Separation for Determination of Isotope Ratios Completed with Revised Uncertainty Evaluation

This study introduces a simplified purification method for analyzing 82Se/78Se isotope ratios in diverse natural samples using hydride generation MC-ICP-MS. Unlike the thiol resin method, which is time-consuming and sensitive to the concentrations of reagents used at individual stages, our proposed...

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Veröffentlicht in:Analytical chemistry (Washington) 2024-03, Vol.96 (9), p.3763-3771
Hauptverfasser: Karasiński, Jakub, Tetfejer, Klaudia, Radziński, Piotr, Tupys, Andrii, Gambin, Anna, Bulska, Ewa, Halicz, Ludwik
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container_end_page 3771
container_issue 9
container_start_page 3763
container_title Analytical chemistry (Washington)
container_volume 96
creator Karasiński, Jakub
Tetfejer, Klaudia
Radziński, Piotr
Tupys, Andrii
Gambin, Anna
Bulska, Ewa
Halicz, Ludwik
description This study introduces a simplified purification method for analyzing 82Se/78Se isotope ratios in diverse natural samples using hydride generation MC-ICP-MS. Unlike the thiol resin method, which is time-consuming and sensitive to the concentrations of reagents used at individual stages, our proposed alternative is quicker, simpler, and robust. The procedure involves coprecipitation of selenium with iron hydroxide and dissolution in hydrochloric acid. Combining hydride generation and a second cleanup stage achieves sufficient purification for Se isotope ratio measurements. The method is efficient, taking 3–4 h after sample decomposition, utilizing common reagents [HCl, Fe­(NO3)3, NH4Cl] without evaporation or clean lab conditions. Results on 82Se/78Se isotope ratios in various matrices are presented, comparing them with literature data. All isotopic results have been subjected to a newly proposed state-of-the-art approach to uncertainty estimation dedicated to isotope ratio measurements. The approach is based on applying Monte Carlo simulations with consideration of different samples’ results normalized by the expected value. By doing that, we obtained estimated uncertainty for any Se sample with the influence of particular measurements on the final estimation included. We employ a Monte Carlo simulation-based uncertainty estimation approach for isotope ratio measurements, providing estimated uncertainty for each selenium sample.
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source American Chemical Society Publications
subjects Ammonium chloride
Coprecipitation
Evaporation
Hydrides
Hydrochloric acid
Iron
Isotope ratios
Monte Carlo simulation
Purification
Ratios
Reagents
Selenium
Uncertainty
title Coprecipitation as a One-Step Se Separation for Determination of Isotope Ratios Completed with Revised Uncertainty Evaluation
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