Advancing our understanding of compound weather and climate events via large ensemble model simulations

Bevacqua, Emanuele; Jézéquel, Aglaé; Suárez-Gutiérrez, Laura; Lehner, Flavio; Vrac, Mathieu; Yiou, Pascal; Zscheischler, Jakob

doi:10.21203/rs.3.rs-1791760/v1

Cited by 2 publications

(2 citation statements)

References 103 publications

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“…SMILEs are also used to investigate ocean ecosystem drivers (Rodgers et al., 2015), and to identify systematic differences between simulated and observed patterns of sea‐surface temperature and sea‐level pressure change that are very unlikely to occur due to internal variability (Olonscheck et al., 2020; Wills et al., 2022). Furthermore, recent developments in compound event research highlight the importance of sufficiently sampling internal variability to robustly capture the risks associated with extreme values of multivariate extremes, which requires even larger ensemble sizes than conventional univariate extremes (Bevacqua et al., 2023; Burger et al., 2022). The availability of SMILEs from multiple models further allows us to better quantify and differentiate sources of uncertainty in climate projections, especially uncertainties arising from internal variability and those from model differences (Deser et al., 2020; Hawkins & Sutton, 2009, 2011; Lehner et al., 2020).…”

Section: Introductionmentioning

confidence: 99%

The New Max Planck Institute Grand Ensemble With CMIP6 Forcing and High‐Frequency Model Output

Olonscheck,

Suarez‐Gutierrez,

Milinski

et al. 2023

J Adv Model Earth Syst

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Single‐model initial‐condition large ensembles are powerful tools to quantify the forced response, internal climate variability, and their evolution under global warming. Here, we present the CMIP6 version of the Max Planck Institute Grand Ensemble (MPI‐GE CMIP6) with currently 30 realizations for the historical period and five emission scenarios. The power of MPI‐GE CMIP6 goes beyond its predecessor ensemble MPI‐GE by providing high‐frequency output, the full range of emission scenarios including the highly policy‐relevant low emission scenarios SSP1‐1.9 and SSP1‐2.6, and the opportunity to compare the ensemble to complementary high‐resolution simulations. First, we describe MPI‐GE CMIP6, evaluate it with observations and reanalyzes and compare it to MPI‐GE. Then, we demonstrate with six application examples how to use the power of the ensemble to better quantify and understand present and future climate extremes, to inform about uncertainty in approaching Paris Agreement global warming limits, and to combine large ensembles and artificial intelligence. For instance, MPI‐GE CMIP6 allows us to show that the recently observed Siberian and Pacific North American heatwaves would only avoid reaching 1–2 years return periods in 2071–2100 with low emission scenarios, that recently observed European precipitation extremes are captured only by complementary high‐resolution simulations, and that 3‐hourly output projects a decreasing activity of storms in mid‐latitude oceans. Further, the ensemble is ideal for estimates of probabilities of crossing global warming limits and the irreducible uncertainty introduced by internal variability, and is sufficiently large to be used for infilling surface temperature observations with artificial intelligence.

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Section: Introductionmentioning

confidence: 99%

The New Max Planck Institute Grand Ensemble With CMIP6 Forcing and High‐Frequency Model Output

Olonscheck,

Suarez‐Gutierrez,

Milinski

et al. 2023

J Adv Model Earth Syst

View full text Add to dashboard Cite

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“…MPI-GE is the largest existing initial-condition ensemble of a comprehensive, fully coupled Earth System Model currently available. This large ensemble size is crucial for robustly sampling and assessing changes in low-probability univariate events, and it is even more important for multivariate compound events and temporally successive extremes 42 . In addition to its large ensemble size, compared to other large ensembles MPI-GE also offers one of the most adequate representations of the historical internal variability and forced changes in observed temperatures 43 and precipitation 44 .…”

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confidence: 99%

End-of-century heat and drought stress approaching Europe swiftly

Suárez-Gutiérrez

Müller

Marotzke

2023

Preprint

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Extreme heat and drought levels typical of an end-of-century climate could occur swiftly, and repeatedly. Despite the European climate being potentially prone to multi-year successive extremes due to the influence of the North Atlantic variability, it remains unclear how the likelihood of such successive extremes changes under warming, how early they could reach end-of-century levels, and how this is affected by internal climate variability. Using the MPI Grand Ensemble, we find that even under moderate warming, end-of-century heat and drought levels virtually impossible 20 years ago reach 1-in-10 likelihoods as early as the 2030s. By 2050-2075, two successive years of single or compound end-of-century extremes, unprecedented to date, exceed 1-in-10 likelihoods; while Europe-wide 5-year megadroughts become plausible. Whole decades of end-of-century heat stress could start by 2040, by 2020 for rain-deficit drought, and end-of-century decades starting as early as 2030 become twice as likely under a warm North Atlantic state.

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Advancing our understanding of compound weather and climate events via large ensemble model simulations

Cited by 2 publications

References 103 publications

The New Max Planck Institute Grand Ensemble With CMIP6 Forcing and High‐Frequency Model Output

The New Max Planck Institute Grand Ensemble With CMIP6 Forcing and High‐Frequency Model Output

End-of-century heat and drought stress approaching Europe swiftly

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