Applications of Machine Learning and Artificial Intelligence in Tropospheric Ozone Research

Sebastian H.M. Hickman; Makoto M. Kelp; Paul T. Griffiths; Kelsey Doerksen; Kazuyuki Miyazaki; Elyse A. Pennington; Gerbrand Koren; Fernando Iglesias-Suarez; Martin G. Schultz; Kai Lan Chang; Owen R. Cooper; Alex Archibald; Roberto Sommariva; David Carlson; Hantao Wang; J. Jason West; Zhenze Liu

doi:10.5194/gmd-18-8777-2025

Applications of Machine Learning and Artificial Intelligence in Tropospheric Ozone Research

Sebastian H.M. Hickman, Makoto M. Kelp, Paul T. Griffiths^*, Kelsey Doerksen, Kazuyuki Miyazaki, Elyse A. Pennington, Gerbrand Koren, Fernando Iglesias-Suarez, Martin G. Schultz, Kai Lan Chang, Owen R. Cooper, Alex Archibald, Roberto Sommariva, David Carlson, Hantao Wang, J. Jason West, Zhenze Liu

^*Corresponding author for this work

Sustainability Science and Education

Research output: Contribution to journal › Review article › peer-review

Abstract

Machine learning (ML) is transforming atmospheric chemistry, offering powerful tools to address challenges in tropospheric ozone research, a critical area for climate resilience and public health. As in adjacent fields, ML approaches complement existing research by learning patterns from ever-increasing volumes of atmospheric and environmental data relevant to ozone. We highlight the rapid progress made in the field since Phase 1 of the Tropospheric Ozone Assessment Report (TOAR), focussing particularly on the most active areas of research, namely short-term ozone forecasting, emulation of atmospheric chemistry and the use of remote sensing for ozone estimation. This review provides a comprehensive synthesis of recent advancements, highlights critical challenges, and proposes actionable pathways to develop ML in ozone research. Further advances hinge on addressing domain-specific issues such as the dependence of ozone concentrations on several poorly observed precursor species, as well as making progress on generic ML challenges such as the definition of suitable benchmarks and developing robust, explainable models. Reaping the full potential of ML for ozone research and operational applications will require close collaborations across atmospheric chemistry, ML and computational science and vigilant pursuit of the rapid developments in adjacent fields.

Original language	English
Pages (from-to)	8777-8800
Number of pages	24
Journal	Geoscientific Model Development
Volume	18
Issue number	22
DOIs	https://doi.org/10.5194/gmd-18-8777-2025
Publication status	Published - 20 Nov 2025

Bibliographical note

Publisher Copyright:
© 2025 Sebastian H. M. Hickman et al.

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Hickman, S. H. M., Kelp, M. M., Griffiths, P. T., Doerksen, K., Miyazaki, K., Pennington, E. A., Koren, G., Iglesias-Suarez, F., Schultz, M. G., Chang, K. L., Cooper, O. R., Archibald, A., Sommariva, R., Carlson, D., Wang, H., Jason West, J., & Liu, Z. (2025). Applications of Machine Learning and Artificial Intelligence in Tropospheric Ozone Research. Geoscientific Model Development, 18(22), 8777-8800. https://doi.org/10.5194/gmd-18-8777-2025

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title = "Applications of Machine Learning and Artificial Intelligence in Tropospheric Ozone Research",

abstract = "Machine learning (ML) is transforming atmospheric chemistry, offering powerful tools to address challenges in tropospheric ozone research, a critical area for climate resilience and public health. As in adjacent fields, ML approaches complement existing research by learning patterns from ever-increasing volumes of atmospheric and environmental data relevant to ozone. We highlight the rapid progress made in the field since Phase 1 of the Tropospheric Ozone Assessment Report (TOAR), focussing particularly on the most active areas of research, namely short-term ozone forecasting, emulation of atmospheric chemistry and the use of remote sensing for ozone estimation. This review provides a comprehensive synthesis of recent advancements, highlights critical challenges, and proposes actionable pathways to develop ML in ozone research. Further advances hinge on addressing domain-specific issues such as the dependence of ozone concentrations on several poorly observed precursor species, as well as making progress on generic ML challenges such as the definition of suitable benchmarks and developing robust, explainable models. Reaping the full potential of ML for ozone research and operational applications will require close collaborations across atmospheric chemistry, ML and computational science and vigilant pursuit of the rapid developments in adjacent fields.",

author = "Hickman, \{Sebastian H.M.\} and Kelp, \{Makoto M.\} and Griffiths, \{Paul T.\} and Kelsey Doerksen and Kazuyuki Miyazaki and Pennington, \{Elyse A.\} and Gerbrand Koren and Fernando Iglesias-Suarez and Schultz, \{Martin G.\} and Chang, \{Kai Lan\} and Cooper, \{Owen R.\} and Alex Archibald and Roberto Sommariva and David Carlson and Hantao Wang and \{Jason West\}, J. and Zhenze Liu",

note = "Publisher Copyright: {\textcopyright} 2025 Sebastian H. M. Hickman et al.",

year = "2025",

month = nov,

day = "20",

doi = "10.5194/gmd-18-8777-2025",

language = "English",

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Hickman, SHM, Kelp, MM, Griffiths, PT, Doerksen, K, Miyazaki, K, Pennington, EA, Koren, G, Iglesias-Suarez, F, Schultz, MG, Chang, KL, Cooper, OR, Archibald, A, Sommariva, R, Carlson, D, Wang, H, Jason West, J & Liu, Z 2025, 'Applications of Machine Learning and Artificial Intelligence in Tropospheric Ozone Research', Geoscientific Model Development, vol. 18, no. 22, pp. 8777-8800. https://doi.org/10.5194/gmd-18-8777-2025

TY - JOUR

T1 - Applications of Machine Learning and Artificial Intelligence in Tropospheric Ozone Research

AU - Hickman, Sebastian H.M.

AU - Kelp, Makoto M.

AU - Griffiths, Paul T.

AU - Doerksen, Kelsey

AU - Miyazaki, Kazuyuki

AU - Pennington, Elyse A.

AU - Koren, Gerbrand

AU - Iglesias-Suarez, Fernando

AU - Schultz, Martin G.

AU - Chang, Kai Lan

AU - Cooper, Owen R.

AU - Archibald, Alex

AU - Sommariva, Roberto

AU - Carlson, David

AU - Wang, Hantao

AU - Jason West, J.

AU - Liu, Zhenze

PY - 2025/11/20

Y1 - 2025/11/20

N2 - Machine learning (ML) is transforming atmospheric chemistry, offering powerful tools to address challenges in tropospheric ozone research, a critical area for climate resilience and public health. As in adjacent fields, ML approaches complement existing research by learning patterns from ever-increasing volumes of atmospheric and environmental data relevant to ozone. We highlight the rapid progress made in the field since Phase 1 of the Tropospheric Ozone Assessment Report (TOAR), focussing particularly on the most active areas of research, namely short-term ozone forecasting, emulation of atmospheric chemistry and the use of remote sensing for ozone estimation. This review provides a comprehensive synthesis of recent advancements, highlights critical challenges, and proposes actionable pathways to develop ML in ozone research. Further advances hinge on addressing domain-specific issues such as the dependence of ozone concentrations on several poorly observed precursor species, as well as making progress on generic ML challenges such as the definition of suitable benchmarks and developing robust, explainable models. Reaping the full potential of ML for ozone research and operational applications will require close collaborations across atmospheric chemistry, ML and computational science and vigilant pursuit of the rapid developments in adjacent fields.

AB - Machine learning (ML) is transforming atmospheric chemistry, offering powerful tools to address challenges in tropospheric ozone research, a critical area for climate resilience and public health. As in adjacent fields, ML approaches complement existing research by learning patterns from ever-increasing volumes of atmospheric and environmental data relevant to ozone. We highlight the rapid progress made in the field since Phase 1 of the Tropospheric Ozone Assessment Report (TOAR), focussing particularly on the most active areas of research, namely short-term ozone forecasting, emulation of atmospheric chemistry and the use of remote sensing for ozone estimation. This review provides a comprehensive synthesis of recent advancements, highlights critical challenges, and proposes actionable pathways to develop ML in ozone research. Further advances hinge on addressing domain-specific issues such as the dependence of ozone concentrations on several poorly observed precursor species, as well as making progress on generic ML challenges such as the definition of suitable benchmarks and developing robust, explainable models. Reaping the full potential of ML for ozone research and operational applications will require close collaborations across atmospheric chemistry, ML and computational science and vigilant pursuit of the rapid developments in adjacent fields.

UR - https://www.scopus.com/pages/publications/105022596914

U2 - 10.5194/gmd-18-8777-2025

DO - 10.5194/gmd-18-8777-2025

M3 - Review article

AN - SCOPUS:105022596914

SN - 1991-959X

VL - 18

SP - 8777

EP - 8800

JO - Geoscientific Model Development

JF - Geoscientific Model Development

IS - 22

ER -

Applications of Machine Learning and Artificial Intelligence in Tropospheric Ozone Research

Abstract

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