Abstract
We have carried out a series of precise Ne-isotope measurements of atmospheric Ne-separates on a state-of-the-art high mass resolution Thermo-Fisher Helix MC Plus Noble Gas Mass Spectrometer. We used a combination of static and dynamic configurations and techniques that allow us to minimize possible analytical artifacts related to isobaric interferences, magnet hysteresis and detector efficiencies. All Ne-isotope signals were measured at high ion beam intensities on accurately intercalibrated Faraday collectors connected to 1012 and 1013 ohm amplifiers, providing linearity and optimal dynamic range and signal/noise ratio. Following consideration of known possible sources of interference, and mass discrimination correction assuming an atmospheric 22Ne/20Ne ratio of 0.102, we derive the relative mass fractionation corrected 21Ne abundance in the terrestrial atmosphere, allowing us to determine a new 21Ne/20Ne ratio of 0.0029577 ± 14. This value is significantly more precise than any previously reported determinations, with implications for atmospheric models and standardization protocols, and potential improvements for the precision and accuracy of terrestrial cosmogenic neon exposure dating, in particular for young exposure ages.
Original language | English |
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Journal | Journal of Analytical Atomic Spectrometry |
Volume | 34 |
Issue number | 3 |
Pages (from-to) | 535-549 |
ISSN | 0267-9477 |
DOIs | |
Publication status | Published - 1 Mar 2019 |