Bringing it all together: Science priorities for improved understanding of Earth system change and to support international climate policy

Colin G. Jones; Fanny Adloff; Ben B.B. Booth; Peter M. Cox; Veronika Eyring; Pierre Friedlingstein; Katja Frieler; Helene T. Hewitt; Hazel A. Jeffery; Sylvie Joussaume; Torben Koenigk; Bryan N. Lawrence; Eleanor O'Rourke; Malcolm J. Roberts; Benjamin M. Sanderson; Roland Séférian; Samuel Somot; Pier Luigi Vidale; Detlef Van Vuuren; Mario Acosta; Mats Bentsen; Raffaele Bernardello; Richard Betts; Ed Blockley; Julien Boé; Tom Bracegirdle; Pascale Braconnot; Victor Brovkin; Carlo Buontempo; Francisco Doblas-Reyes; Markus Donat; Italo Epicoco; Pete Falloon; Sandro Fiore; Thomas Frölicher; Neven S. Fučkar; Matthew J. Gidden; Helge F. Goessling; Rune Grand Graversen; Silvio Gualdi; José M. Gutiérrez; Tatiana Ilyina; Daniela Jacob; Chris D. Jones; Martin Juckes; Elizabeth Kendon; Erik Kjellström; Reto Knutti; Jason Lowe; Matthew Mizielinski; Paola Nassisi; Michael Obersteiner; Pierre Regnier; Romain Roehrig; David Salas Y Mélia; Carl Friedrich Schleussner; Michael Schulz; Enrico Scoccimarro; Laurent Terray; Hannes Thiemann; Richard A. Wood; Shuting Yang; Sönke Zaehle

doi:10.5194/esd-15-1319-2024

Bringing it all together: Science priorities for improved understanding of Earth system change and to support international climate policy

Colin G. Jones^*, Fanny Adloff, Ben B.B. Booth, Peter M. Cox, Veronika Eyring, Pierre Friedlingstein, Katja Frieler, Helene T. Hewitt, Hazel A. Jeffery, Sylvie Joussaume, Torben Koenigk, Bryan N. Lawrence, Eleanor O'Rourke, Malcolm J. Roberts, Benjamin M. Sanderson, Roland Séférian, Samuel Somot, Pier Luigi Vidale, Detlef Van Vuuren, Mario AcostaMats Bentsen, Raffaele Bernardello, Richard Betts, Ed Blockley, Julien Boé, Tom Bracegirdle, Pascale Braconnot, Victor Brovkin, Carlo Buontempo, Francisco Doblas-Reyes, Markus Donat, Italo Epicoco, Pete Falloon, Sandro Fiore, Thomas Frölicher, Neven S. Fučkar, Matthew J. Gidden, Helge F. Goessling, Rune Grand Graversen, Silvio Gualdi, José M. Gutiérrez, Tatiana Ilyina, Daniela Jacob, Chris D. Jones, Martin Juckes, Elizabeth Kendon, Erik Kjellström, Reto Knutti, Jason Lowe, Matthew Mizielinski, Paola Nassisi, Michael Obersteiner, Pierre Regnier, Romain Roehrig, David Salas Y Mélia, Carl Friedrich Schleussner, Michael Schulz, Enrico Scoccimarro, Laurent Terray, Hannes Thiemann, Richard A. Wood, Shuting Yang, Sönke Zaehle

^*Corresponding author for this work

Environmental Sciences

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

Abstract

We review how the international modelling community, encompassing integrated assessment models, global and regional Earth system and climate models, and impact models, has worked together over the past few decades to advance understanding of Earth system change and its impacts on society and the environment and thereby support international climate policy. We go on to recommend a number of priority research areas for the coming decade, a timescale that encompasses a number of newly starting international modelling activities, as well as the IPCC Seventh Assessment Report (AR7) and the second UNFCCC Global Stocktake. Progress in these priority areas will significantly advance our understanding of Earth system change and its impacts, increasing the quality and utility of science support to climate policy. We emphasize the need for continued improvement in our understanding of, and ability to simulate, the coupled Earth system and the impacts of Earth system change. There is an urgent need to investigate plausible pathways and emission scenarios that realize the Paris climate targets - for example, pathways that overshoot 1.5 or 2 °C global warming, before returning to these levels at some later date. Earth system models need to be capable of thoroughly assessing such warming overshoots - in particular, the efficacy of mitigation measures, such as negative CO2 emissions, in reducing atmospheric CO2 and driving global cooling. An improved assessment of the long-term consequences of stabilizing climate at 1.5 or 2 °C above pre-industrial temperatures is also required. We recommend Earth system models run overshoot scenarios in CO2-emission mode to more fully represent coupled climate-carbon-cycle feedbacks and, wherever possible, interactively simulate other key Earth system phenomena at risk of rapid change during overshoot. Regional downscaling and impact models should use forcing data from these simulations, so impact and regional climate projections cover a more complete range of potential responses to a warming overshoot. An accurate simulation of the observed, historical record remains a fundamental requirement of models, as does accurate simulation of key metrics, such as the effective climate sensitivity and the transient climate response to cumulative carbon emissions. For adaptation, a key demand is improved guidance on potential changes in climate extremes and the modes of variability these extremes develop within. Such improvements will most likely be realized through a combination of increased model resolution, improvement of key model parameterizations, and enhanced representation of important Earth system processes, combined with targeted use of new artificial intelligence (AI) and machine learning (ML) techniques. We propose a deeper collaboration across such efforts over the coming decade. With respect to sampling future uncertainty, increased collaboration between approaches that emphasize large model ensembles and those focussed on statistical emulation is required. We recommend an increased focus on high-impact-low-likelihood (HILL) outcomes - in particular, the risk and consequences of exceeding critical tipping points during a warming overshoot and the potential impacts arising from this. For a comprehensive assessment of the impacts of Earth system change, including impacts arising directly as a result of climate mitigation actions, it is important that spatially detailed, disaggregated information used to generate future scenarios in integrated assessment models be available for use in impact models. Conversely, there is a need to develop methods that enable potential societal responses to projected Earth system change to be incorporated into scenario development. The new models, simulations, data, and scientific advances proposed in this article will not be possible without long-term development and maintenance of a robust, globally connected infrastructure ecosystem. This system must be easily accessible and useable by modelling communities across the world, allowing the global research community to be fully engaged in developing and delivering new scientific knowledge to support international climate policy.

Original language	English
Pages (from-to)	1319-1351
Number of pages	33
Journal	Earth System Dynamics
Volume	15
Issue number	5
DOIs	https://doi.org/10.5194/esd-15-1319-2024
Publication status	Published - 18 Oct 2024

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Publisher Copyright:
Copyright © 2024 Colin G. Jones et al.

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Jones, C. G., Adloff, F., Booth, B. B. B., Cox, P. M., Eyring, V., Friedlingstein, P., Frieler, K., Hewitt, H. T., Jeffery, H. A., Joussaume, S., Koenigk, T., Lawrence, B. N., O'Rourke, E., Roberts, M. J., Sanderson, B. M., Séférian, R., Somot, S., Vidale, P. L., Van Vuuren, D., ... Zaehle, S. (2024). Bringing it all together: Science priorities for improved understanding of Earth system change and to support international climate policy. Earth System Dynamics, 15(5), 1319-1351. https://doi.org/10.5194/esd-15-1319-2024

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abstract = "We review how the international modelling community, encompassing integrated assessment models, global and regional Earth system and climate models, and impact models, has worked together over the past few decades to advance understanding of Earth system change and its impacts on society and the environment and thereby support international climate policy. We go on to recommend a number of priority research areas for the coming decade, a timescale that encompasses a number of newly starting international modelling activities, as well as the IPCC Seventh Assessment Report (AR7) and the second UNFCCC Global Stocktake. Progress in these priority areas will significantly advance our understanding of Earth system change and its impacts, increasing the quality and utility of science support to climate policy. We emphasize the need for continued improvement in our understanding of, and ability to simulate, the coupled Earth system and the impacts of Earth system change. There is an urgent need to investigate plausible pathways and emission scenarios that realize the Paris climate targets - for example, pathways that overshoot 1.5 or 2 °C global warming, before returning to these levels at some later date. Earth system models need to be capable of thoroughly assessing such warming overshoots - in particular, the efficacy of mitigation measures, such as negative CO2 emissions, in reducing atmospheric CO2 and driving global cooling. An improved assessment of the long-term consequences of stabilizing climate at 1.5 or 2 °C above pre-industrial temperatures is also required. We recommend Earth system models run overshoot scenarios in CO2-emission mode to more fully represent coupled climate-carbon-cycle feedbacks and, wherever possible, interactively simulate other key Earth system phenomena at risk of rapid change during overshoot. Regional downscaling and impact models should use forcing data from these simulations, so impact and regional climate projections cover a more complete range of potential responses to a warming overshoot. An accurate simulation of the observed, historical record remains a fundamental requirement of models, as does accurate simulation of key metrics, such as the effective climate sensitivity and the transient climate response to cumulative carbon emissions. For adaptation, a key demand is improved guidance on potential changes in climate extremes and the modes of variability these extremes develop within. Such improvements will most likely be realized through a combination of increased model resolution, improvement of key model parameterizations, and enhanced representation of important Earth system processes, combined with targeted use of new artificial intelligence (AI) and machine learning (ML) techniques. We propose a deeper collaboration across such efforts over the coming decade. With respect to sampling future uncertainty, increased collaboration between approaches that emphasize large model ensembles and those focussed on statistical emulation is required. We recommend an increased focus on high-impact-low-likelihood (HILL) outcomes - in particular, the risk and consequences of exceeding critical tipping points during a warming overshoot and the potential impacts arising from this. For a comprehensive assessment of the impacts of Earth system change, including impacts arising directly as a result of climate mitigation actions, it is important that spatially detailed, disaggregated information used to generate future scenarios in integrated assessment models be available for use in impact models. Conversely, there is a need to develop methods that enable potential societal responses to projected Earth system change to be incorporated into scenario development. The new models, simulations, data, and scientific advances proposed in this article will not be possible without long-term development and maintenance of a robust, globally connected infrastructure ecosystem. This system must be easily accessible and useable by modelling communities across the world, allowing the global research community to be fully engaged in developing and delivering new scientific knowledge to support international climate policy.",

author = "Jones, \{Colin G.\} and Fanny Adloff and Booth, \{Ben B.B.\} and Cox, \{Peter M.\} and Veronika Eyring and Pierre Friedlingstein and Katja Frieler and Hewitt, \{Helene T.\} and Jeffery, \{Hazel A.\} and Sylvie Joussaume and Torben Koenigk and Lawrence, \{Bryan N.\} and Eleanor O'Rourke and Roberts, \{Malcolm J.\} and Sanderson, \{Benjamin M.\} and Roland S{\'e}f{\'e}rian and Samuel Somot and Vidale, \{Pier Luigi\} and \{Van Vuuren\}, Detlef and Mario Acosta and Mats Bentsen and Raffaele Bernardello and Richard Betts and Ed Blockley and Julien Bo{\'e} and Tom Bracegirdle and Pascale Braconnot and Victor Brovkin and Carlo Buontempo and Francisco Doblas-Reyes and Markus Donat and Italo Epicoco and Pete Falloon and Sandro Fiore and Thomas Fr{\"o}licher and Fu{\v c}kar, \{Neven S.\} and Gidden, \{Matthew J.\} and Goessling, \{Helge F.\} and Graversen, \{Rune Grand\} and Silvio Gualdi and Guti{\'e}rrez, \{Jos{\'e} M.\} and Tatiana Ilyina and Daniela Jacob and Jones, \{Chris D.\} and Martin Juckes and Elizabeth Kendon and Erik Kjellstr{\"o}m and Reto Knutti and Jason Lowe and Matthew Mizielinski and Paola Nassisi and Michael Obersteiner and Pierre Regnier and Romain Roehrig and \{Salas Y M{\'e}lia\}, David and Schleussner, \{Carl Friedrich\} and Michael Schulz and Enrico Scoccimarro and Laurent Terray and Hannes Thiemann and Wood, \{Richard A.\} and Shuting Yang and S{\"o}nke Zaehle",

note = "Publisher Copyright: Copyright {\textcopyright} 2024 Colin G. Jones et al.",

year = "2024",

month = oct,

day = "18",

doi = "10.5194/esd-15-1319-2024",

language = "English",

volume = "15",

pages = "1319--1351",

journal = "Earth System Dynamics",

issn = "2190-4979",

publisher = "Copernicus Publications",

number = "5",

}

Jones, CG, Adloff, F, Booth, BBB, Cox, PM, Eyring, V, Friedlingstein, P, Frieler, K, Hewitt, HT, Jeffery, HA, Joussaume, S, Koenigk, T, Lawrence, BN, O'Rourke, E, Roberts, MJ, Sanderson, BM, Séférian, R, Somot, S, Vidale, PL, Van Vuuren, D, Acosta, M, Bentsen, M, Bernardello, R, Betts, R, Blockley, E, Boé, J, Bracegirdle, T, Braconnot, P, Brovkin, V, Buontempo, C, Doblas-Reyes, F, Donat, M, Epicoco, I, Falloon, P, Fiore, S, Frölicher, T, Fučkar, NS, Gidden, MJ, Goessling, HF, Graversen, RG, Gualdi, S, Gutiérrez, JM, Ilyina, T, Jacob, D, Jones, CD, Juckes, M, Kendon, E, Kjellström, E, Knutti, R, Lowe, J, Mizielinski, M, Nassisi, P, Obersteiner, M, Regnier, P, Roehrig, R, Salas Y Mélia, D, Schleussner, CF, Schulz, M, Scoccimarro, E, Terray, L, Thiemann, H, Wood, RA, Yang, S & Zaehle, S 2024, 'Bringing it all together: Science priorities for improved understanding of Earth system change and to support international climate policy', Earth System Dynamics, vol. 15, no. 5, pp. 1319-1351. https://doi.org/10.5194/esd-15-1319-2024

TY - JOUR

T1 - Bringing it all together

T2 - Science priorities for improved understanding of Earth system change and to support international climate policy

AU - Jones, Colin G.

AU - Adloff, Fanny

AU - Booth, Ben B.B.

AU - Cox, Peter M.

AU - Eyring, Veronika

AU - Friedlingstein, Pierre

AU - Frieler, Katja

AU - Hewitt, Helene T.

AU - Jeffery, Hazel A.

AU - Joussaume, Sylvie

AU - Koenigk, Torben

AU - Lawrence, Bryan N.

AU - O'Rourke, Eleanor

AU - Roberts, Malcolm J.

AU - Sanderson, Benjamin M.

AU - Séférian, Roland

AU - Somot, Samuel

AU - Vidale, Pier Luigi

AU - Van Vuuren, Detlef

AU - Acosta, Mario

AU - Bentsen, Mats

AU - Bernardello, Raffaele

AU - Betts, Richard

AU - Blockley, Ed

AU - Boé, Julien

AU - Bracegirdle, Tom

AU - Braconnot, Pascale

AU - Brovkin, Victor

AU - Buontempo, Carlo

AU - Doblas-Reyes, Francisco

AU - Donat, Markus

AU - Epicoco, Italo

AU - Falloon, Pete

AU - Fiore, Sandro

AU - Frölicher, Thomas

AU - Fučkar, Neven S.

AU - Gidden, Matthew J.

AU - Goessling, Helge F.

AU - Graversen, Rune Grand

AU - Gualdi, Silvio

AU - Gutiérrez, José M.

AU - Ilyina, Tatiana

AU - Jacob, Daniela

AU - Jones, Chris D.

AU - Juckes, Martin

AU - Kendon, Elizabeth

AU - Kjellström, Erik

AU - Knutti, Reto

AU - Lowe, Jason

AU - Mizielinski, Matthew

AU - Nassisi, Paola

AU - Obersteiner, Michael

AU - Regnier, Pierre

AU - Roehrig, Romain

AU - Salas Y Mélia, David

AU - Schleussner, Carl Friedrich

AU - Schulz, Michael

AU - Scoccimarro, Enrico

AU - Terray, Laurent

AU - Thiemann, Hannes

AU - Wood, Richard A.

AU - Yang, Shuting

AU - Zaehle, Sönke

PY - 2024/10/18

Y1 - 2024/10/18

N2 - We review how the international modelling community, encompassing integrated assessment models, global and regional Earth system and climate models, and impact models, has worked together over the past few decades to advance understanding of Earth system change and its impacts on society and the environment and thereby support international climate policy. We go on to recommend a number of priority research areas for the coming decade, a timescale that encompasses a number of newly starting international modelling activities, as well as the IPCC Seventh Assessment Report (AR7) and the second UNFCCC Global Stocktake. Progress in these priority areas will significantly advance our understanding of Earth system change and its impacts, increasing the quality and utility of science support to climate policy. We emphasize the need for continued improvement in our understanding of, and ability to simulate, the coupled Earth system and the impacts of Earth system change. There is an urgent need to investigate plausible pathways and emission scenarios that realize the Paris climate targets - for example, pathways that overshoot 1.5 or 2 °C global warming, before returning to these levels at some later date. Earth system models need to be capable of thoroughly assessing such warming overshoots - in particular, the efficacy of mitigation measures, such as negative CO2 emissions, in reducing atmospheric CO2 and driving global cooling. An improved assessment of the long-term consequences of stabilizing climate at 1.5 or 2 °C above pre-industrial temperatures is also required. We recommend Earth system models run overshoot scenarios in CO2-emission mode to more fully represent coupled climate-carbon-cycle feedbacks and, wherever possible, interactively simulate other key Earth system phenomena at risk of rapid change during overshoot. Regional downscaling and impact models should use forcing data from these simulations, so impact and regional climate projections cover a more complete range of potential responses to a warming overshoot. An accurate simulation of the observed, historical record remains a fundamental requirement of models, as does accurate simulation of key metrics, such as the effective climate sensitivity and the transient climate response to cumulative carbon emissions. For adaptation, a key demand is improved guidance on potential changes in climate extremes and the modes of variability these extremes develop within. Such improvements will most likely be realized through a combination of increased model resolution, improvement of key model parameterizations, and enhanced representation of important Earth system processes, combined with targeted use of new artificial intelligence (AI) and machine learning (ML) techniques. We propose a deeper collaboration across such efforts over the coming decade. With respect to sampling future uncertainty, increased collaboration between approaches that emphasize large model ensembles and those focussed on statistical emulation is required. We recommend an increased focus on high-impact-low-likelihood (HILL) outcomes - in particular, the risk and consequences of exceeding critical tipping points during a warming overshoot and the potential impacts arising from this. For a comprehensive assessment of the impacts of Earth system change, including impacts arising directly as a result of climate mitigation actions, it is important that spatially detailed, disaggregated information used to generate future scenarios in integrated assessment models be available for use in impact models. Conversely, there is a need to develop methods that enable potential societal responses to projected Earth system change to be incorporated into scenario development. The new models, simulations, data, and scientific advances proposed in this article will not be possible without long-term development and maintenance of a robust, globally connected infrastructure ecosystem. This system must be easily accessible and useable by modelling communities across the world, allowing the global research community to be fully engaged in developing and delivering new scientific knowledge to support international climate policy.

AB - We review how the international modelling community, encompassing integrated assessment models, global and regional Earth system and climate models, and impact models, has worked together over the past few decades to advance understanding of Earth system change and its impacts on society and the environment and thereby support international climate policy. We go on to recommend a number of priority research areas for the coming decade, a timescale that encompasses a number of newly starting international modelling activities, as well as the IPCC Seventh Assessment Report (AR7) and the second UNFCCC Global Stocktake. Progress in these priority areas will significantly advance our understanding of Earth system change and its impacts, increasing the quality and utility of science support to climate policy. We emphasize the need for continued improvement in our understanding of, and ability to simulate, the coupled Earth system and the impacts of Earth system change. There is an urgent need to investigate plausible pathways and emission scenarios that realize the Paris climate targets - for example, pathways that overshoot 1.5 or 2 °C global warming, before returning to these levels at some later date. Earth system models need to be capable of thoroughly assessing such warming overshoots - in particular, the efficacy of mitigation measures, such as negative CO2 emissions, in reducing atmospheric CO2 and driving global cooling. An improved assessment of the long-term consequences of stabilizing climate at 1.5 or 2 °C above pre-industrial temperatures is also required. We recommend Earth system models run overshoot scenarios in CO2-emission mode to more fully represent coupled climate-carbon-cycle feedbacks and, wherever possible, interactively simulate other key Earth system phenomena at risk of rapid change during overshoot. Regional downscaling and impact models should use forcing data from these simulations, so impact and regional climate projections cover a more complete range of potential responses to a warming overshoot. An accurate simulation of the observed, historical record remains a fundamental requirement of models, as does accurate simulation of key metrics, such as the effective climate sensitivity and the transient climate response to cumulative carbon emissions. For adaptation, a key demand is improved guidance on potential changes in climate extremes and the modes of variability these extremes develop within. Such improvements will most likely be realized through a combination of increased model resolution, improvement of key model parameterizations, and enhanced representation of important Earth system processes, combined with targeted use of new artificial intelligence (AI) and machine learning (ML) techniques. We propose a deeper collaboration across such efforts over the coming decade. With respect to sampling future uncertainty, increased collaboration between approaches that emphasize large model ensembles and those focussed on statistical emulation is required. We recommend an increased focus on high-impact-low-likelihood (HILL) outcomes - in particular, the risk and consequences of exceeding critical tipping points during a warming overshoot and the potential impacts arising from this. For a comprehensive assessment of the impacts of Earth system change, including impacts arising directly as a result of climate mitigation actions, it is important that spatially detailed, disaggregated information used to generate future scenarios in integrated assessment models be available for use in impact models. Conversely, there is a need to develop methods that enable potential societal responses to projected Earth system change to be incorporated into scenario development. The new models, simulations, data, and scientific advances proposed in this article will not be possible without long-term development and maintenance of a robust, globally connected infrastructure ecosystem. This system must be easily accessible and useable by modelling communities across the world, allowing the global research community to be fully engaged in developing and delivering new scientific knowledge to support international climate policy.

UR - https://www.scopus.com/pages/publications/85208289512

U2 - 10.5194/esd-15-1319-2024

DO - 10.5194/esd-15-1319-2024

M3 - Article

AN - SCOPUS:85208289512

SN - 2190-4979

VL - 15

SP - 1319

EP - 1351

JO - Earth System Dynamics

JF - Earth System Dynamics

IS - 5

ER -

Bringing it all together: Science priorities for improved understanding of Earth system change and to support international climate policy

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