Storylines of summer Arctic climate change constrained by Barents-Kara seas and Arctic tropospheric warming for climate risk assessment

Xavier J. Levine; Ryan S. Williams; Gareth Marshall; Andrew Orr; Lise Seland Graff; Dörthe Handorf; Alexey Karpechko; Raphael Köhler; René R. Wijngaard; Nadine Johnston; Hanna Lee; Lars Nieradzik; Priscilla A. Mooney

doi:10.5194/esd-15-1161-2024

Storylines of summer Arctic climate change constrained by Barents-Kara seas and Arctic tropospheric warming for climate risk assessment

Xavier J. Levine^*, Ryan S. Williams, Gareth Marshall, Andrew Orr, Lise Seland Graff, Dörthe Handorf, Alexey Karpechko, Raphael Köhler, René R. Wijngaard, Nadine Johnston, Hanna Lee, Lars Nieradzik, Priscilla A. Mooney

^*Corresponding author for this work

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

Abstract

While climate models broadly agree on the changes expected to occur over the Arctic with global warming on a pan-Arctic scale (i.e. polar amplification, sea ice loss, and increased precipitation), the magnitude and patterns of these changes at regional and local scales remain uncertain. This limits the usability of climate model projections for risk assessments and their impact on human activities or ecosystems (e.g. fires and permafrost thawing). Whereas any single or ensemble mean projection may be of limited use to stakeholders, recent studies have shown the value of the storyline approach in providing a comprehensive and tractable set of climate projections that can be used to evaluate changes in environmental or societal risks associated with global warming. Here, we apply the storyline approach to a large ensemble of the Coupled Model Intercomparison Project Phase 6 (CMIP6) models with the aim of distilling the wide spread in model predictions into four physically plausible outcomes of Arctic summertime climate change. This is made possible by leveraging strong covariability in the climate system associated with well-known but poorly constrained teleconnections and local processes; specifically, we find that differences in Barents-Kara sea warming and lower-tropospheric warming over polar regions among CMIP6 models explain most of the inter-model variability in pan-Arctic surface summer climate response to global warming. Based on this novel finding, we compare regional disparities in climate change across the four storylines. Our storyline analysis highlights the fact that for a given amount of global warming, certain climate risks can be intensified, while others may be lessened, relative to a "middle-of-the-road"ensemble mean projection. We find this to be particularly relevant when comparing climate change over terrestrial and marine areas of the Arctic which can show substantial differences in their sensitivity to global warming. We conclude by discussing the potential implications of our findings for modelling climate change impacts on ecosystems and human activities.

Original language	English
Pages (from-to)	1161-1177
Number of pages	17
Journal	Earth System Dynamics
Volume	15
Issue number	4
DOIs	https://doi.org/10.5194/esd-15-1161-2024
Publication status	Published - 26 Aug 2024

Bibliographical note

Publisher Copyright:
© Author(s) 2024.

Funding

We acknowledge the support of PolarRES (grant no. 101003590), a project of the European Union's Horizon 2020 research and innovation programme. Storage and computing resources necessary to conduct the analysis were provided by Sigma2 - the national infrastructure for high-performance computing and data storage in Norway (project nos. NS8002K and NN8002K). The CMIP6 simulations used for this analysis were obtained from the Earth System Grid Federation (ESGF), an infrastructure supported by the World Climate Research Programme (WCRP). Financial support. This research has been supported by the EU H2020 Environment (grant no. 101003590). This research has been supported by the EU H2020 Environment (grant no. 101003590).

Funders	Funder number
Earth System Grid Federation
Horizon 2020	NN8002K, NS8002K
H2020 Environment	101003590

UN SDGs

This output contributes to the following UN Sustainable Development Goals (SDGs)

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Cite this

Levine, X. J., Williams, R. S., Marshall, G., Orr, A., Seland Graff, L., Handorf, D., Karpechko, A., Köhler, R., Wijngaard, R. R., Johnston, N., Lee, H., Nieradzik, L., & Mooney, P. A. (2024). Storylines of summer Arctic climate change constrained by Barents-Kara seas and Arctic tropospheric warming for climate risk assessment. Earth System Dynamics, 15(4), 1161-1177. https://doi.org/10.5194/esd-15-1161-2024

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abstract = "While climate models broadly agree on the changes expected to occur over the Arctic with global warming on a pan-Arctic scale (i.e. polar amplification, sea ice loss, and increased precipitation), the magnitude and patterns of these changes at regional and local scales remain uncertain. This limits the usability of climate model projections for risk assessments and their impact on human activities or ecosystems (e.g. fires and permafrost thawing). Whereas any single or ensemble mean projection may be of limited use to stakeholders, recent studies have shown the value of the storyline approach in providing a comprehensive and tractable set of climate projections that can be used to evaluate changes in environmental or societal risks associated with global warming. Here, we apply the storyline approach to a large ensemble of the Coupled Model Intercomparison Project Phase 6 (CMIP6) models with the aim of distilling the wide spread in model predictions into four physically plausible outcomes of Arctic summertime climate change. This is made possible by leveraging strong covariability in the climate system associated with well-known but poorly constrained teleconnections and local processes; specifically, we find that differences in Barents-Kara sea warming and lower-tropospheric warming over polar regions among CMIP6 models explain most of the inter-model variability in pan-Arctic surface summer climate response to global warming. Based on this novel finding, we compare regional disparities in climate change across the four storylines. Our storyline analysis highlights the fact that for a given amount of global warming, certain climate risks can be intensified, while others may be lessened, relative to a {"}middle-of-the-road{"}ensemble mean projection. We find this to be particularly relevant when comparing climate change over terrestrial and marine areas of the Arctic which can show substantial differences in their sensitivity to global warming. We conclude by discussing the potential implications of our findings for modelling climate change impacts on ecosystems and human activities.",

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month = aug,

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Levine, XJ, Williams, RS, Marshall, G, Orr, A, Seland Graff, L, Handorf, D, Karpechko, A, Köhler, R, Wijngaard, RR, Johnston, N, Lee, H, Nieradzik, L & Mooney, PA 2024, 'Storylines of summer Arctic climate change constrained by Barents-Kara seas and Arctic tropospheric warming for climate risk assessment', Earth System Dynamics, vol. 15, no. 4, pp. 1161-1177. https://doi.org/10.5194/esd-15-1161-2024

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AU - Seland Graff, Lise

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AU - Köhler, Raphael

AU - Wijngaard, René R.

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AU - Nieradzik, Lars

AU - Mooney, Priscilla A.

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Storylines of summer Arctic climate change constrained by Barents-Kara seas and Arctic tropospheric warming for climate risk assessment

Abstract

Bibliographical note

Funding

UN SDGs

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