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Methane and carbon dioxide fluxes and their regional scalability for the European Arctic wetlands during the MAMM project in summer 2012

O'Shea, Sebastian J; Allen, Grant; Gallagher, Martin W; Bower, K; Illingworth, SM; Muller, JBA; Jones, Benjamin T; Percival, CJ; Bauguitte, S; Cain, Michelle; Warwick, N.; Quiquet, A.; Skiba, U.; Drewer, J.; Dinsmore, K.; Nisbet, E.G.; Lowry, D.; Fisher, R.E.; France, J.L.; Aurela, M.; Lohila, A.; Hayman, G.; George, C.; Clark, D.B.; Manning, A.J.; Friend, A.D.; Pyle, J.

Authors

Sebastian J O'Shea

Grant Allen

Martin W Gallagher

K Bower

JBA Muller

Benjamin T Jones

CJ Percival

S Bauguitte

Michelle Cain

N. Warwick

A. Quiquet

U. Skiba

J. Drewer

K. Dinsmore

E.G. Nisbet

D. Lowry

R.E. Fisher

J.L. France

M. Aurela

A. Lohila

G. Hayman

C. George

D.B. Clark

A.J. Manning

A.D. Friend

J. Pyle



Abstract

Airborne and ground-based measurements of methane (CH4), carbon dioxide (CO2) and boundary layer thermodynamics were recorded over the Fennoscandian landscape (67–69.5° N, 20–28° E) in July 2012 as part of the MAMM (Methane and other greenhouse gases in the Arctic: Measurements, process studies and Modelling) field campaign. Employing these airborne measurements and a simple boundary layer box model, net regional-scale (~ 100 km) fluxes were calculated to be 1.2 ± 0.5 mg CH4 h−1 m−2 and −350 ± 143 mg CO2 h−1 m−2. These airborne fluxes were found to be relatively consistent with seasonally averaged surface chamber (1.3 ± 1.0 mg CH4 h−1 m−2) and eddy covariance (1.3 ± 0.3 mg CH4 h−1 m−2 and −309 ± 306 mg CO2 h−1 m−2) flux measurements in the local area. The internal consistency of the aircraft-derived fluxes across a wide swath of Fennoscandia coupled with an excellent statistical comparison with local seasonally averaged ground-based measurements demonstrates the potential scalability of such localised measurements to regional-scale representativeness. Comparisons were also made to longer-term regional CH4 climatologies from the JULES (Joint UK Land Environment Simulator) and HYBRID8 land surface models within the area of the MAMM campaign. The average hourly emission flux output for the summer period (July–August) for the year 2012 was 0.084 mg CH4 h−1 m−2 (minimum 0.0 and maximum 0.21 mg CH4 h−1 m−2) for the JULES model and 0.088 mg CH4 h−1 m−2 (minimum 0.0008 and maximum 1.53 mg CH4 h−1 m−2) for HYBRID8. Based on these observations both models were found to significantly underestimate the CH4 emission flux in this region, which was linked to the under-prediction of the wetland extents generated by the models.

Citation

O'Shea, S. J., Allen, G., Gallagher, M. W., Bower, K., Illingworth, S., Muller, J., …Pyle, J. (2014). Methane and carbon dioxide fluxes and their regional scalability for the European Arctic wetlands during the MAMM project in summer 2012. Atmospheric Chemistry and Physics, 14(23), 13159-13174. https://doi.org/10.5194/acp-14-13159-2014

Journal Article Type Article
Acceptance Date Oct 31, 2014
Online Publication Date Dec 10, 2014
Publication Date 2014
Deposit Date Feb 15, 2021
Publicly Available Date Feb 15, 2021
Journal Atmospheric Chemistry and Physics
Print ISSN 1680-7316
Publisher European Geosciences Union
Peer Reviewed Peer Reviewed
Volume 14
Issue 23
Pages 13159-13174
DOI https://doi.org/10.5194/acp-14-13159-2014
Public URL http://researchrepository.napier.ac.uk/Output/2736620

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Methane And Carbon Dioxide Fluxes And Their Regional Scalability For The European Arctic Wetlands During The MAMM Project In Summer 2012 (2.4 Mb)
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Publisher Licence URL
http://creativecommons.org/licenses/by/4.0/

Copyright Statement
© Author(s) 2014. This work is distributed under the Creative Commons Attribution 3.0 License.




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