Your search keyword '"L. Emmenegger"' showing total 2 results

1. First investigation and absolute calibration of clumped isotopes in N 2 O by mid-infrared laser spectroscopy.

Author

Kantnerová K, Yu L, Zindel D, Zahniser MS, Nelson DD, Tuzson B, Nakagawa M, Toyoda S, Yoshida N, Emmenegger L, Bernasconi SM, and Mohn J

Abstract

Rationale: Unravelling the biogeochemical cycle of the potent greenhouse gas nitrous oxide (N 2 O) is an underdetermined problem in environmental sciences due to the multiple source and sink processes involved, which complicate mitigation of its emissions. Measuring the doubly isotopically substituted molecules (isotopocules) of N 2 O can add new opportunities to fingerprint and constrain its cycle., Methods: We present a laser spectroscopic technique to selectively and simultaneously measure the eight most abundant isotopocules of N 2 O, including three doubly substituted species - so called "clumped isotopes". For the absolute quantification of individual isotopocule abundances, we propose a new calibration scheme that combines thermal equilibration of a working standard gas with a direct mole fraction-based approach., Results: The method is validated for a large range of isotopic composition values by comparison with other established methods (laser spectroscopy using conventional isotopic scale and isotope ratio mass spectrometry). Direct intercomparison with recently developed ultrahigh-resolution mass spectrometry shows clearly the advantages of the new laser technique, especially with respect to site specificity of isotopic substitution in the N 2 O molecule., Conclusions: Our study represents a new methodological basis for the measurements of both singly substituted and clumped N 2 O isotopes. It has a high potential to stimulate future research in the N 2 O community by establishing a new class of reservoir-insensitive tracers and molecular-scale insights., (© 2020 John Wiley & Sons, Ltd.)

Published

2020

2. Novel laser spectroscopic technique for continuous analysis of N2O isotopomers--application and intercomparison with isotope ratio mass spectrometry.

Author

Köster JR, Well R, Tuzson B, Bol R, Dittert K, Giesemann A, Emmenegger L, Manninen A, Cárdenas L, and Mohn J

Subjects

Lasers, Semiconductor, Nitrates chemistry, Nitrogen Isotopes chemistry, Nitrous Oxide chemistry, Nitrous Oxide metabolism, Oxygen Isotopes chemistry, Reproducibility of Results, Soil chemistry, Spectrophotometry, Infrared instrumentation, Spectrophotometry, Infrared methods, Sucrose chemistry, Mass Spectrometry methods, Nitrogen Isotopes analysis, Nitrous Oxide analysis, Oxygen Isotopes analysis

Abstract

Rationale: Nitrous oxide (N(2)O), a highly climate-relevant trace gas, is mainly derived from microbial denitrification and nitrification processes in soils. Apportioning N(2)O to these source processes is a challenging task, but better understanding of the processes is required to improve mitigation strategies. The N(2)O site-specific (15)N signatures from denitrification and nitrification have been shown to be clearly different, making this signature a potential tool for N(2)O source identification. We have applied for the first time quantum cascade laser absorption spectroscopy (QCLAS) for the continuous analysis of the intramolecular (15)N distribution of soil-derived N(2)O and compared this with state-of-the-art isotope ratio mass spectrometry (IRMS)., Methods: Soil was amended with nitrate and sucrose and incubated in a laboratory setup. The N(2)O release was quantified by FTIR spectroscopy, while the N(2)O intramolecular (15)N distribution was continuously analyzed by online QCLAS at 1 Hz resolution. The QCLAS results on time-integrating flask samples were compared with those from the IRMS analysis., Results: The analytical precision (2σ) of QCLAS was around 0.3‰ for the δ(15)N(bulk) and the (15)N site preference (SP) for 1-min average values. Comparing the two techniques on flask samples, excellent agreement (R(2)= 0.99; offset of 1.2‰) was observed for the δ(15)N(bulk) values while for the SP values the correlation was less good (R(2 )= 0.76; offset of 0.9‰), presumably due to the lower precision of the IRMS SP measurements., Conclusions: These findings validate QCLAS as a viable alternative technique with even higher precision than state-of-the-art IRMS. Thus, laser spectroscopy has the potential to contribute significantly to a better understanding of N turnover in soils, which is crucial for advancing strategies to mitigate emissions of this efficient greenhouse gas., (Copyright © 2012 John Wiley & Sons, Ltd.)

Published

2013