Determination of Trace Se and Te in Geological Samples by Photochemical Vapour Generation Combined with Inductively Coupled Plasma‐Mass Spectrometry

An analytical method to accurately determine trace levels of Se and Te is essential to meet the growing importance of these elements to Earth science research. Herein, an in‐house assembled photochemical vapour generation (PVG) unit, instead of normal sample nebulisation, with inductively coupled pl...

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Published in:Geostandards and geoanalytical research 2024-03, Vol.48 (1), p.133-143
Main Authors: Yuan, Yonghai, Han, Zhixuan, Yang, Feng, Yu, Hongxia, Zhang, Yinhui, Wen, Meilan
Format: Article
Language:English
Subjects:
Acetic acid
Analytical methods
Cobalt
geological sample
Geological samples
Geology
inductively coupled plasma‐mass spectrometry
Irradiation
Mass spectrometry
Mass spectroscopy
photochemical vapour generation
Photochemicals
Photochemistry
Scientific imaging
Trace levels
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Summary:An analytical method to accurately determine trace levels of Se and Te is essential to meet the growing importance of these elements to Earth science research. Herein, an in‐house assembled photochemical vapour generation (PVG) unit, instead of normal sample nebulisation, with inductively coupled plasma‐mass spectrometry (ICP‐MS), was developed for the detection of Se and Te in geological samples. The major parameters that might potentially influence the PVG efficiencies of Se(IV) and Te(IV) were investigated. The unit could fully generate volatile species under 30 s of ultraviolet irradiation in the presence of 15% v/v formic acid, 15% v/v acetic acid and 50 mg l‐1 of Co2+. Under optimised conditions, the limit of detections (LODs, 3s, n = 11) of the proposed method were 0.5 ng l‐1 for Se and 0.6 ng l‐1 for Te. The RSDs of Se and Te were 2.0% and 2.3% (1 μg l‐1, n = 7), respectively. Interference experiments showed that Fe, Ti, V and Cu have certain negative effects, so the standard addition method was used for real sample analysis. Measurement results for eleven CRMs, including soils (GSS‐4, GSS‐7), sediments (GSD‐9, GSD‐10) and rocks (GSR‐1, GSR‐2, GSR‐3, GSR‐5, AGV‐2, GSP‐2 and W‐2a), were consistent with literature values, and showed better precision, indicating the feasibility of the proposed method for determination of trace Se and Te in geological samples. Key Points An in‐house assembled PVG unit combined with ICP‐MS was developed for the determination of Se and Te in geological samples. The standard addition method was used for real sample analysis to avoid negative interference by Fe3+, Ti3+, V5+ and Cu2+. The proposed method was verified using eleven certified reference materials.
ISSN:1639-4488
1751-908X
DOI:10.1111/ggr.12539