TY - JOUR
T1 - Bayesian atmospheric tomography for detection and quantification of methane emissions
T2 - application to data from the 2015 Ginninderra release experiment
AU - Cartwright, Laura
AU - Zammit-Mangion, Andrew
AU - Bhatia, Sangeeta
AU - Schroder, Ivan
AU - Phillips, Frances
AU - Coates, Trevor
AU - Negandhi, Karita
AU - Naylor, Travis
AU - Kennedy, Martin
AU - Zegelin, Steve
AU - Wokker, Nick
AU - Deutscher, Nicholas M.
AU - Feitz, Andrew
N1 - Copyright the Author(s) 2019. Version archived for private and non-commercial use with the permission of the author/s and according to publisher conditions. For further rights please contact the publisher.
PY - 2019/9/2
Y1 - 2019/9/2
N2 - Detection and quantification of greenhouse-gas emissions is important for both compliance and environment conservation. However, despite several decades of active research, it remains predominantly an open problem, largely due to model errors and assumptions that appear at each stage of the inversion processing chain. In 2015, a controlled-release experiment headed by Geoscience Australia was carried out at the Ginninderra Controlled Release Facility, and a variety of instruments and methods were employed for quantifying the release rates of methane and carbon dioxide from a point source. This paper proposes a fully Bayesian approach to atmospheric tomography for inferring the methane emission rate of this point source using data collected during the experiment from both point-and path-sampling instruments. The Bayesian framework is designed to account for uncertainty in the parameterisations of measurements, the meteorological data, and the atmospheric model itself when performing inversion using Markov chain Monte Carlo (MCMC). We apply our framework to all instrument groups using measurements from two release-rate periods. We show that the inversion framework is robust to instrument type and meteorological conditions. From all the inversions we conducted across the different instrument groups and release-rate periods, our worst-case median emission rate estimate was within 36 % of the true emission rate. Further, in the worst case, the closest limit of the 95 % credible interval to the true emission rate was within 11 % of this true value.
AB - Detection and quantification of greenhouse-gas emissions is important for both compliance and environment conservation. However, despite several decades of active research, it remains predominantly an open problem, largely due to model errors and assumptions that appear at each stage of the inversion processing chain. In 2015, a controlled-release experiment headed by Geoscience Australia was carried out at the Ginninderra Controlled Release Facility, and a variety of instruments and methods were employed for quantifying the release rates of methane and carbon dioxide from a point source. This paper proposes a fully Bayesian approach to atmospheric tomography for inferring the methane emission rate of this point source using data collected during the experiment from both point-and path-sampling instruments. The Bayesian framework is designed to account for uncertainty in the parameterisations of measurements, the meteorological data, and the atmospheric model itself when performing inversion using Markov chain Monte Carlo (MCMC). We apply our framework to all instrument groups using measurements from two release-rate periods. We show that the inversion framework is robust to instrument type and meteorological conditions. From all the inversions we conducted across the different instrument groups and release-rate periods, our worst-case median emission rate estimate was within 36 % of the true emission rate. Further, in the worst case, the closest limit of the 95 % credible interval to the true emission rate was within 11 % of this true value.
UR - http://www.scopus.com/inward/record.url?scp=85071779757&partnerID=8YFLogxK
UR - http://purl.org/au-research/grants/arc/DE180100203
UR - http://purl.org/au-research/grants/arc/FT180100327
U2 - 10.5194/amt-12-4659-2019
DO - 10.5194/amt-12-4659-2019
M3 - Article
AN - SCOPUS:85071779757
SN - 1867-1381
VL - 12
SP - 4659
EP - 4676
JO - Atmospheric Measurement Techniques
JF - Atmospheric Measurement Techniques
IS - 9
ER -