RATIONALE: In recent years, research and applications of the N2O site-specific nitrogen isotope composition have advanced, reflecting awareness of the contribution of N2O to the anthropogenic greenhouse effect, and leading to significant progress in instrument development. Further dissemination of N2O isotopomer analysis, however, is hampered by a lack of internationally agreed gaseous N2O reference materials and an uncertain compatibility of different laboratories and analytical techniques. METHODS: In a first comparison approach, eleven laboratories were each provided with N2O at tropospheric mole fractions (target gas T) and two reference gases (REF1 and REF2). The laboratories analysed all gases, applying their specific analytical routines. Compatibility of laboratories was assessed based on N2O isotopocule data for T, REF1 and REF2. Results for T were then standardised using REF1 and REF2 to evaluate the potential of N2O reference materials for improving compatibility between laboratories. RESULTS: Compatibility between laboratories depended on the analytical technique: isotope ratio mass spectrometry (IRMS) results showed better compatibility for δ(15)N values, while the performance of laser spectroscopy was superior with respect to N2O site preference. This comparison, however, is restricted by the small number of participating laboratories applying laser spectroscopy. Offset and two-point calibration correction of the N2O isotopomer data significantly improved the consistency of position-dependent nitrogen isotope data while the effect on δ(15)N values was only minor. CONCLUSIONS: The study reveals that for future research on N2O isotopocules, standardisation against N2O reference material is essential to improve interlaboratory compatibility. For atmospheric monitoring activities, we suggest N2O in whole air as a unifying scale anchor.
RATIONALE: In recent years, research and applications of the N2O site-specific nitrogen isotope composition have advanced, reflecting awareness of the contribution of N2O to the anthropogenic greenhouse effect, and leading to significant progress in instrument development. Further dissemination of N2O isotopomer analysis, however, is hampered by a lack of internationally agreed gaseous N2O reference materials and an uncertain compatibility of different laboratories and analytical techniques. METHODS: In a first comparison approach, eleven laboratories were each provided with N2O at tropospheric mole fractions (target gas T) and two reference gases (REF1 and REF2). The laboratories analysed all gases, applying their specific analytical routines. Compatibility of laboratories was assessed based on N2O isotopocule data for T, REF1 and REF2. Results for T were then standardised using REF1 and REF2 to evaluate the potential of N2O reference materials for improving compatibility between laboratories. RESULTS: Compatibility between laboratories depended on the analytical technique: isotope ratio mass spectrometry (IRMS) results showed better compatibility for δ(15)N values, while the performance of laser spectroscopy was superior with respect to N2O site preference. This comparison, however, is restricted by the small number of participating laboratories applying laser spectroscopy. Offset and two-point calibration correction of the N2O isotopomer data significantly improved the consistency of position-dependent nitrogen isotope data while the effect on δ(15)N values was only minor. CONCLUSIONS: The study reveals that for future research on N2O isotopocules, standardisation against N2O reference material is essential to improve interlaboratory compatibility. For atmospheric monitoring activities, we suggest N2O in whole air as a unifying scale anchor.
Authors: Joachim Mohn; Christina Biasi; Samuel Bodé; Pascal Boeckx; Paul J Brewer; Sarah Eggleston; Heike Geilmann; Myriam Guillevic; Jan Kaiser; Kristýna Kantnerová; Heiko Moossen; Joanna Müller; Mayuko Nakagawa; Ruth Pearce; Isabell von Rein; David Steger; Sakae Toyoda; Wolfgang Wanek; Sarah K Wexler; Naohiro Yoshida; Longfei Yu Journal: Rapid Commun Mass Spectrom Date: 2022-07-15 Impact factor: 2.586
Authors: D S Grundle; C R Löscher; G Krahmann; M A Altabet; H W Bange; J Karstensen; A Körtzinger; B Fiedler Journal: Sci Rep Date: 2017-07-06 Impact factor: 4.379
Authors: E Harris; E Diaz-Pines; E Stoll; M Schloter; S Schulz; C Duffner; K Li; K L Moore; J Ingrisch; D Reinthaler; S Zechmeister-Boltenstern; S Glatzel; N Brüggemann; M Bahn Journal: Sci Adv Date: 2021-02-05 Impact factor: 14.136
Authors: Nicole A Kratochwil; Stephen R Dueker; Dieter Muri; Claudia Senn; HyeJin Yoon; Byung-Yong Yu; Gwan-Ho Lee; Feng Dong; Michael B Otteneder Journal: PLoS One Date: 2018-10-17 Impact factor: 3.240