Development and First Deployment of an Innovative Airborne δ13C(CH4) In Situ Measurement Setup

This thesis introduces an innovative in situ airborne system for the measurement of the stable carbon isotope ratio of methane emitters, called MIRACLE (measurement of methane stable carbon isotope ratio by airborne implementation of a cavity ring down laser spectrometer). A conventional Picarro gre...

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Bibliographic Details
Main Author: Waldmann, Paul
Format: Thesis
Language:English
Published: 2023
Subjects:
Atmosphärische Spurenstoffe
Arctic
Online Access:https://elib.dlr.de/193673/
https://elib.dlr.de/193673/1/MA_Waldmann_final.pdf
id ftdlr:oai:elib.dlr.de:193673
record_format openpolar
spelling ftdlr:oai:elib.dlr.de:193673 2023-05-15T15:12:53+02:00 Development and First Deployment of an Innovative Airborne δ13C(CH4) In Situ Measurement Setup Waldmann, Paul 2023-01 application/pdf https://elib.dlr.de/193673/ https://elib.dlr.de/193673/1/MA_Waldmann_final.pdf en eng https://elib.dlr.de/193673/1/MA_Waldmann_final.pdf Waldmann, Paul (2023) Development and First Deployment of an Innovative Airborne δ13C(CH4) In Situ Measurement Setup. Masterarbeit, Ludwig-Maximilians Universität München. Atmosphärische Spurenstoffe Hochschulschrift NonPeerReviewed 2023 ftdlr 2023-02-06T00:15:26Z This thesis introduces an innovative in situ airborne system for the measurement of the stable carbon isotope ratio of methane emitters, called MIRACLE (measurement of methane stable carbon isotope ratio by airborne implementation of a cavity ring down laser spectrometer). A conventional Picarro greenhouse gas analyser was used for the measurement of methane and the methane carbon isotope ratio aboard the research aircraft HALO during the CoMet 2.0 Arctic campaign. Precise δ13C(CH4) measurements were achieved by the supplement of a new type of sample collector to the analyser, which makes it possible to take up to six gas samples in a short time, for an extended period of subsequent analysis. The extended measurement period allows analysis with a δ13C(CH4) 1σ uncertainty of 0.34 ‰ aboard the aircraft. The MIRACLE instrument was tested for contamination of the samples but showed no distortion of the methane concentration or the isotope ratio. For two of the successful research flights of the campaign, the isotopic signatures of the target areas were analysed using the data of MIRACLE, in order to highlight the measurement uncertainties of the instrument and to discuss the results in the context of the literature. The δ13C(CH4) signature of the lake Winnipeg wetland area was found to be -61.95 ± 2.56‰, which is in accordance with comparable studies. The δ13C(CH4) signature of a biomass burning fire plume was found to be -35.33 ± 8.58‰, also consistent with the literature. The MIRACLE instrument combines the advantages of high precision δ13C(CH4) measurements, which were previously only possible under stable laboratory conditions, with the in situ, real time data analysis and large-scale sampling of secluded areas, due to the airborne deployment. Thesis Arctic German Aerospace Center: elib - DLR electronic library Arctic
institution Open Polar
collection German Aerospace Center: elib - DLR electronic library
op_collection_id ftdlr
language English
topic Atmosphärische Spurenstoffe
spellingShingle Atmosphärische Spurenstoffe
Waldmann, Paul
Development and First Deployment of an Innovative Airborne δ13C(CH4) In Situ Measurement Setup
topic_facet Atmosphärische Spurenstoffe
description This thesis introduces an innovative in situ airborne system for the measurement of the stable carbon isotope ratio of methane emitters, called MIRACLE (measurement of methane stable carbon isotope ratio by airborne implementation of a cavity ring down laser spectrometer). A conventional Picarro greenhouse gas analyser was used for the measurement of methane and the methane carbon isotope ratio aboard the research aircraft HALO during the CoMet 2.0 Arctic campaign. Precise δ13C(CH4) measurements were achieved by the supplement of a new type of sample collector to the analyser, which makes it possible to take up to six gas samples in a short time, for an extended period of subsequent analysis. The extended measurement period allows analysis with a δ13C(CH4) 1σ uncertainty of 0.34 ‰ aboard the aircraft. The MIRACLE instrument was tested for contamination of the samples but showed no distortion of the methane concentration or the isotope ratio. For two of the successful research flights of the campaign, the isotopic signatures of the target areas were analysed using the data of MIRACLE, in order to highlight the measurement uncertainties of the instrument and to discuss the results in the context of the literature. The δ13C(CH4) signature of the lake Winnipeg wetland area was found to be -61.95 ± 2.56‰, which is in accordance with comparable studies. The δ13C(CH4) signature of a biomass burning fire plume was found to be -35.33 ± 8.58‰, also consistent with the literature. The MIRACLE instrument combines the advantages of high precision δ13C(CH4) measurements, which were previously only possible under stable laboratory conditions, with the in situ, real time data analysis and large-scale sampling of secluded areas, due to the airborne deployment.
format Thesis
author Waldmann, Paul
author_facet Waldmann, Paul
author_sort Waldmann, Paul
title Development and First Deployment of an Innovative Airborne δ13C(CH4) In Situ Measurement Setup
title_short Development and First Deployment of an Innovative Airborne δ13C(CH4) In Situ Measurement Setup
title_full Development and First Deployment of an Innovative Airborne δ13C(CH4) In Situ Measurement Setup
title_fullStr Development and First Deployment of an Innovative Airborne δ13C(CH4) In Situ Measurement Setup
title_full_unstemmed Development and First Deployment of an Innovative Airborne δ13C(CH4) In Situ Measurement Setup
title_sort development and first deployment of an innovative airborne δ13c(ch4) in situ measurement setup
publishDate 2023
url https://elib.dlr.de/193673/
https://elib.dlr.de/193673/1/MA_Waldmann_final.pdf
geographic Arctic
geographic_facet Arctic
genre Arctic
genre_facet Arctic
op_relation https://elib.dlr.de/193673/1/MA_Waldmann_final.pdf
Waldmann, Paul (2023) Development and First Deployment of an Innovative Airborne δ13C(CH4) In Situ Measurement Setup. Masterarbeit, Ludwig-Maximilians Universität München.
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