Automated detection and monitoring of methane super-emitters using satellite data

Berend J. Schuit; Joannes D. Maasakkers; Pieter Bijl; Gourav Mahapatra; Anne Wil Van Den Berg; Sudhanshu Pandey; Alba Lorente; Tobias Borsdorff; Sander Houweling; Daniel J. Varon; Jason McKeever; Dylan Jervis; Marianne Girard; Itziar Irakulis-Loitxate; Javier Gorroño; Luis Guanter; Daniel H. Cusworth; Ilse Aben

doi:10.5194/acp-23-9071-2023

Automated detection and monitoring of methane super-emitters using satellite data

Berend J. Schuit^*, Joannes D. Maasakkers, Pieter Bijl, Gourav Mahapatra, Anne Wil Van Den Berg, Sudhanshu Pandey, Alba Lorente, Tobias Borsdorff, Sander Houweling, Daniel J. Varon, Jason McKeever, Dylan Jervis, Marianne Girard, Itziar Irakulis-Loitxate, Javier Gorroño, Luis Guanter, Daniel H. Cusworth, Ilse Aben

^*Corresponding author for this work

Earth Sciences

Research output: Contribution to Journal › Article › Academic › peer-review

Abstract

A reduction in anthropogenic methane emissions is vital to limit near-term global warming. A small number of so-called super-emitters is responsible for a disproportionally large fraction of total methane emissions. Since late 2017, the TROPOspheric Monitoring Instrument (TROPOMI) has been in orbit, providing daily global coverage of methane mixing ratios at a resolution of up to 7×5.5 km2, enabling the detection of these super-emitters. However, TROPOMI produces millions of observations each day, which together with the complexity of the methane data, makes manual inspection infeasible. We have therefore designed a two-step machine learning approach using a convolutional neural network to detect plume-like structures in the methane data and subsequently apply a support vector classifier to distinguish the emission plumes from retrieval artifacts. The models are trained on pre-2021 data and subsequently applied to all 2021 observations. We detect 2974 plumes in 2021, with a mean estimated source rate of 44 t h-1 and 5-95th percentile range of 8-122 t h-1. These emissions originate from 94 persistent emission clusters and hundreds of transient sources. Based on bottom-up emission inventories, we find that most detected plumes are related to urban areas and/or landfills (35 %), followed by plumes from gas infrastructure (24 %), oil infrastructure (21 %), and coal mines (20 %). For 12 (clusters of) TROPOMI detections, we tip and cue the targeted observations and analysis of high-resolution satellite instruments to identify the exact sources responsible for these plumes. Using high-resolution observations from GHGSat, PRISMA, and Sentinel-2, we detect and analyze both persistent and transient facility-level emissions underlying the TROPOMI detections. We find emissions from landfills and fossil fuel exploitation facilities, and for the latter, we find up to 10 facilities contributing to one TROPOMI detection. Our automated TROPOMI-based monitoring system in combination with high-resolution satellite data allows for the detection, precise identification, and monitoring of these methane super-emitters, which is essential for mitigating their emissions.

Original language	English
Pages (from-to)	9071-9098
Number of pages	28
Journal	Atmospheric Chemistry and Physics
Volume	23
Issue number	16
Early online date	19 Sept 2023
DOIs	https://doi.org/10.5194/acp-23-9071-2023
Publication status	Published - 2023

Bibliographical note

Funding Information:
This work has been supported by the NSO TROPOMI national program for Alba Lorente, the GALES project (grant no. 15597) of the Dutch Technology Foundation STW-NWO for Sudhanshu Pandey, and ESA through EDAP for Gourav Mahapatra.

Publisher Copyright:
© 2023 Copernicus GmbH. All rights reserved.

Funding

This work has been supported by the NSO TROPOMI national program for Alba Lorente, the GALES project (grant no. 15597) of the Dutch Technology Foundation STW-NWO for Sudhanshu Pandey, and ESA through EDAP for Gourav Mahapatra.

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Schuit, B. J., Maasakkers, J. D., Bijl, P., Mahapatra, G., Van Den Berg, A. W., Pandey, S., Lorente, A., Borsdorff, T., Houweling, S., Varon, D. J., McKeever, J., Jervis, D., Girard, M., Irakulis-Loitxate, I., Gorroño, J., Guanter, L., Cusworth, D. H., & Aben, I. (2023). Automated detection and monitoring of methane super-emitters using satellite data. Atmospheric Chemistry and Physics, 23(16), 9071-9098. https://doi.org/10.5194/acp-23-9071-2023

@article{ebf68056d52f49f4b2ca8c586d27ee56,

title = "Automated detection and monitoring of methane super-emitters using satellite data",

abstract = "A reduction in anthropogenic methane emissions is vital to limit near-term global warming. A small number of so-called super-emitters is responsible for a disproportionally large fraction of total methane emissions. Since late 2017, the TROPOspheric Monitoring Instrument (TROPOMI) has been in orbit, providing daily global coverage of methane mixing ratios at a resolution of up to 7×5.5 km2, enabling the detection of these super-emitters. However, TROPOMI produces millions of observations each day, which together with the complexity of the methane data, makes manual inspection infeasible. We have therefore designed a two-step machine learning approach using a convolutional neural network to detect plume-like structures in the methane data and subsequently apply a support vector classifier to distinguish the emission plumes from retrieval artifacts. The models are trained on pre-2021 data and subsequently applied to all 2021 observations. We detect 2974 plumes in 2021, with a mean estimated source rate of 44 t h-1 and 5-95th percentile range of 8-122 t h-1. These emissions originate from 94 persistent emission clusters and hundreds of transient sources. Based on bottom-up emission inventories, we find that most detected plumes are related to urban areas and/or landfills (35 %), followed by plumes from gas infrastructure (24 %), oil infrastructure (21 %), and coal mines (20 %). For 12 (clusters of) TROPOMI detections, we tip and cue the targeted observations and analysis of high-resolution satellite instruments to identify the exact sources responsible for these plumes. Using high-resolution observations from GHGSat, PRISMA, and Sentinel-2, we detect and analyze both persistent and transient facility-level emissions underlying the TROPOMI detections. We find emissions from landfills and fossil fuel exploitation facilities, and for the latter, we find up to 10 facilities contributing to one TROPOMI detection. Our automated TROPOMI-based monitoring system in combination with high-resolution satellite data allows for the detection, precise identification, and monitoring of these methane super-emitters, which is essential for mitigating their emissions.",

author = "Schuit, {Berend J.} and Maasakkers, {Joannes D.} and Pieter Bijl and Gourav Mahapatra and {Van Den Berg}, {Anne Wil} and Sudhanshu Pandey and Alba Lorente and Tobias Borsdorff and Sander Houweling and Varon, {Daniel J.} and Jason McKeever and Dylan Jervis and Marianne Girard and Itziar Irakulis-Loitxate and Javier Gorro{\~n}o and Luis Guanter and Cusworth, {Daniel H.} and Ilse Aben",

note = "Funding Information: This work has been supported by the NSO TROPOMI national program for Alba Lorente, the GALES project (grant no. 15597) of the Dutch Technology Foundation STW-NWO for Sudhanshu Pandey, and ESA through EDAP for Gourav Mahapatra. Publisher Copyright: {\textcopyright} 2023 Copernicus GmbH. All rights reserved.",

year = "2023",

doi = "10.5194/acp-23-9071-2023",

language = "English",

volume = "23",

pages = "9071--9098",

journal = "Atmospheric Chemistry and Physics",

issn = "1680-7316",

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Schuit, BJ, Maasakkers, JD, Bijl, P, Mahapatra, G, Van Den Berg, AW, Pandey, S, Lorente, A, Borsdorff, T, Houweling, S, Varon, DJ, McKeever, J, Jervis, D, Girard, M, Irakulis-Loitxate, I, Gorroño, J, Guanter, L, Cusworth, DH & Aben, I 2023, 'Automated detection and monitoring of methane super-emitters using satellite data', Atmospheric Chemistry and Physics, vol. 23, no. 16, pp. 9071-9098. https://doi.org/10.5194/acp-23-9071-2023

TY - JOUR

T1 - Automated detection and monitoring of methane super-emitters using satellite data

AU - Schuit, Berend J.

AU - Maasakkers, Joannes D.

AU - Bijl, Pieter

AU - Mahapatra, Gourav

AU - Van Den Berg, Anne Wil

AU - Pandey, Sudhanshu

AU - Lorente, Alba

AU - Borsdorff, Tobias

AU - Houweling, Sander

AU - Varon, Daniel J.

AU - McKeever, Jason

AU - Jervis, Dylan

AU - Girard, Marianne

AU - Irakulis-Loitxate, Itziar

AU - Gorroño, Javier

AU - Guanter, Luis

AU - Cusworth, Daniel H.

AU - Aben, Ilse

N1 - Funding Information: This work has been supported by the NSO TROPOMI national program for Alba Lorente, the GALES project (grant no. 15597) of the Dutch Technology Foundation STW-NWO for Sudhanshu Pandey, and ESA through EDAP for Gourav Mahapatra. Publisher Copyright: © 2023 Copernicus GmbH. All rights reserved.

PY - 2023

Y1 - 2023

N2 - A reduction in anthropogenic methane emissions is vital to limit near-term global warming. A small number of so-called super-emitters is responsible for a disproportionally large fraction of total methane emissions. Since late 2017, the TROPOspheric Monitoring Instrument (TROPOMI) has been in orbit, providing daily global coverage of methane mixing ratios at a resolution of up to 7×5.5 km2, enabling the detection of these super-emitters. However, TROPOMI produces millions of observations each day, which together with the complexity of the methane data, makes manual inspection infeasible. We have therefore designed a two-step machine learning approach using a convolutional neural network to detect plume-like structures in the methane data and subsequently apply a support vector classifier to distinguish the emission plumes from retrieval artifacts. The models are trained on pre-2021 data and subsequently applied to all 2021 observations. We detect 2974 plumes in 2021, with a mean estimated source rate of 44 t h-1 and 5-95th percentile range of 8-122 t h-1. These emissions originate from 94 persistent emission clusters and hundreds of transient sources. Based on bottom-up emission inventories, we find that most detected plumes are related to urban areas and/or landfills (35 %), followed by plumes from gas infrastructure (24 %), oil infrastructure (21 %), and coal mines (20 %). For 12 (clusters of) TROPOMI detections, we tip and cue the targeted observations and analysis of high-resolution satellite instruments to identify the exact sources responsible for these plumes. Using high-resolution observations from GHGSat, PRISMA, and Sentinel-2, we detect and analyze both persistent and transient facility-level emissions underlying the TROPOMI detections. We find emissions from landfills and fossil fuel exploitation facilities, and for the latter, we find up to 10 facilities contributing to one TROPOMI detection. Our automated TROPOMI-based monitoring system in combination with high-resolution satellite data allows for the detection, precise identification, and monitoring of these methane super-emitters, which is essential for mitigating their emissions.

AB - A reduction in anthropogenic methane emissions is vital to limit near-term global warming. A small number of so-called super-emitters is responsible for a disproportionally large fraction of total methane emissions. Since late 2017, the TROPOspheric Monitoring Instrument (TROPOMI) has been in orbit, providing daily global coverage of methane mixing ratios at a resolution of up to 7×5.5 km2, enabling the detection of these super-emitters. However, TROPOMI produces millions of observations each day, which together with the complexity of the methane data, makes manual inspection infeasible. We have therefore designed a two-step machine learning approach using a convolutional neural network to detect plume-like structures in the methane data and subsequently apply a support vector classifier to distinguish the emission plumes from retrieval artifacts. The models are trained on pre-2021 data and subsequently applied to all 2021 observations. We detect 2974 plumes in 2021, with a mean estimated source rate of 44 t h-1 and 5-95th percentile range of 8-122 t h-1. These emissions originate from 94 persistent emission clusters and hundreds of transient sources. Based on bottom-up emission inventories, we find that most detected plumes are related to urban areas and/or landfills (35 %), followed by plumes from gas infrastructure (24 %), oil infrastructure (21 %), and coal mines (20 %). For 12 (clusters of) TROPOMI detections, we tip and cue the targeted observations and analysis of high-resolution satellite instruments to identify the exact sources responsible for these plumes. Using high-resolution observations from GHGSat, PRISMA, and Sentinel-2, we detect and analyze both persistent and transient facility-level emissions underlying the TROPOMI detections. We find emissions from landfills and fossil fuel exploitation facilities, and for the latter, we find up to 10 facilities contributing to one TROPOMI detection. Our automated TROPOMI-based monitoring system in combination with high-resolution satellite data allows for the detection, precise identification, and monitoring of these methane super-emitters, which is essential for mitigating their emissions.

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Automated detection and monitoring of methane super-emitters using satellite data

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