Benefits of sea ice initialization for the interannual-to-decadal climate prediction skill in the Arctic in EC-Earth3

Tian, Tian; Yang, Shuting; Karami, Mehdi Pasha; Massonnet, François; Kruschke, Tim; Köenigk, Torben

doi:10.5194/gmd-14-4283-2021

Cited by 8 publications

(7 citation statements)

References 64 publications

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“…It is worth mentioning that the variable such as SST with minor additional contributions to the model does not mean that it is a minor contributor since the contributions from different variables to prediction skill partially overlap. In addition, adding SIT to the model has a substantial contribution to the prediction skill in the warm season, indicating that sea ice thickness is a key source of sea ice predictability within the Arctic Basin in the warm season, especially in summer, which is consistent with previous studies (Blanchard-Wrigglesworth et al, 2011;Blockley and Peterson, 2018;Day et al, 2014a;Morioka et al, 2021;Tian et al, 2021;Yuan et al, 2016). However, SIT has a negative contribution to the prediction skill in the cold season (Fig.…”

Section: Construction Of An Optimal Model For Each Seasonsupporting

confidence: 90%

“…The results show that SIC is highly related to OHC in the upper 300 m, SIT, SST, SAT, surface net radiative flux, surface net turbulent heat flux, and geopotential height (GPH) and wind vector at different levels, including 850 to 200 hPa. Due to the barotropic nature of the polar troposphere (Chen, 2005;Ting, 1994) and the low correlation between sea-level pressure and SIC, we chose GPH and wind vector at 850 hPa to define the lowlevel atmospheric circulation, whose interaction with sea ice is stronger relative to that in higher levels. Therefore, we choose to define the coupled atmosphere-ice-ocean Arctic climate system with nine variables: SIC, OHC in the upper 300 m, SIT, SST, SAT, surface net radiative flux, surface net turbulent heat flux, 850 hPa GPH, and 850 hPa wind vector.…”

Section: Datamentioning

confidence: 99%

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Reassessing seasonal sea ice predictability of the Pacific-Arctic sector using a Markov model

Wang

Yuan

et al. 2022

The Cryosphere

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Abstract. In this study, a regional linear Markov model is developed to assess seasonal sea ice predictability in the Pacific-Arctic sector. Unlike an earlier pan-Arctic Markov model that was developed with one set of variables for all seasons, the regional model consists of four seasonal modules with different sets of predictor variables, accommodating seasonally varying driving processes. A series of sensitivity tests are performed to evaluate the predictive skill in cross-validated experiments and to determine the best model configuration for each season. The prediction skill, as measured by the sea ice concentration (SIC) anomaly correlation coefficient (ACC) between predictions and observations, increased by 32 % in the Bering Sea and 18 % in the Sea of Okhotsk relative to the pan-Arctic model. The regional Markov model's skill is also superior to the skill of an anomaly persistence forecast. SIC trends significantly contribute to the model skill. However, the model retains skill for detrended sea ice extent predictions for up to 7-month lead times in the Bering Sea and the Sea of Okhotsk. We find that subsurface ocean heat content (OHC) provides a crucial source of prediction skill in all seasons, especially in the cold season, and adding sea ice thickness (SIT) to the regional Markov model has a substantial contribution to the prediction skill in the warm season but a negative contribution in the cold season. The regional model can also capture the seasonal reemergence of predictability, which is missing in the pan-Arctic model.

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Section: Construction Of An Optimal Model For Each Seasonsupporting

confidence: 90%

Section: Datamentioning

confidence: 99%

Reassessing seasonal sea ice predictability of the Pacific-Arctic sector using a Markov model

Wang

Yuan

et al. 2022

The Cryosphere

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“…Sea ice drift pathways changed significantly between different years even for ice floes originating from the same location (Krumpen et al, 2021). The spatial distribution of liquid freshwater and ocean surface circulation in the Arctic Ocean have varied considerably over recent decades (e.g., Timmermans et al, 2011;Wang et al, 2019c;Polyakov et al, 2020), which could have contributed to the changes in sea ice drift pathways, besides the direct impact of winds. Our finding also addresses that the changes in ocean surface geostrophic currents must be taken into account in the calculation of ice-ocean stress.…”

Section: Discussionmentioning

confidence: 99%

“…Q. Wang et al: Impact of the Arctic Ocean's memory on sea ice improving the prediction of Arctic sea ice and climate (e.g., Tian et al, 2021). Previous analysis of the role of ocean initialization has mainly been focused on the impact of ocean temperature.…”

mentioning

confidence: 99%

Lasting impact of winds on Arctic sea ice through the ocean's memory

Wang

Danilov

et al. 2021

The Cryosphere

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Abstract. In this paper we studied the impact of winds on Arctic sea ice through the ocean's memory by using numerical simulations. We found that the changes in halosteric height induced by wind perturbations can significantly affect the Arctic sea ice drift, thickness, concentration and deformation rates regionally even years after the wind perturbations. Changes in the Arctic liquid freshwater content and thus in halosteric height can cause changes in the sea surface height and surface geostrophic currents, which further enforce a lasting and strong impact on sea ice. The changes in both sea surface height gradient force (due to changes in sea surface height) and ice–ocean stress (due to changes in surface geostrophic currents) are found to be important in determining the overall ocean effects. The revealed ocean effects are mainly associated with changes in sea ice dynamics, not thermodynamics. Depending on the preceding atmospheric mode driving the ocean, the ocean's memory of the wind forcing can lead to changes in Arctic sea ice characteristics with very different spatial patterns. We obtained these spatial patterns associated with Arctic Oscillation, Arctic Dipole Anomaly and Beaufort High modes through dedicated numerical simulations. The dynamical impact of the ocean has strong seasonal variations, stronger in summer and weaker in winter and spring. This implies that declining trends of Arctic sea ice will very possibly allow a stronger ocean impact on the sea ice in a warming climate.

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“…Assimilation of observed SIC in retrospective forecasts initialized on May 1st improves Arctic sea ice predictions in May-June, and October-November. The largest improvements in the sea ice edge representation are found in the Greenland-Norwegian-Iceland (GIN) Seas, a region where EC-Earth3 is known to have important systematic sea ice biases (Cruz-García et al 2021, Tian et al 2021). Better skill in SIC also leads to improved central North Atlantic SST forecasts already in May via a fast (sub-monthly scale) atmospheric pathway, evidenced by increased prediction skill of GPH500 and T2m in the first weeks of May over the North Atlantic.…”

Section: Discussionmentioning

confidence: 99%

Added value of assimilating springtime Arctic sea ice concentration in summer-fall climate predictions

Navarro

Garcı́a-Serrano

Lapin

et al. 2022

Environ. Res. Lett.

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Prediction skill of continental climate in the Northern Hemisphere midlatitudes is generally limited throughout the year in dynamical seasonal forecast systems. Such limitations narrow the range of possible applications by different stakeholders. Improving the predictive capacity in these regions has been a challenging task. Sea ice is a central component of the Arctic climate system and a local source of climate predictability, yet its state is often not fully constrained in dynamical forecast systems. Using the EC-Earth3 climate model, we study the added value of assimilating observed Arctic sea ice concentration (SIC) on the Northern Hemisphere extratropical climate in retrospective forecasts of summer and fall, initialized every spring over 1992-2019. Predictions in the North Atlantic and Eurasia benefit from better initialization of sea ice in the Atlantic sector of the Arctic in a two-step mechanism. Initially, sea ice influences the central North Atlantic Ocean through an atmospheric bridge that develops in the first forecast weeks, subsequently leading to preserved skill in the sea surface temperatures throughout summer and early fall. Secondly, these long-lasting sea surface temperature improvements provide better surface boundary conditions for the atmosphere and lead to more skillful predictions of circulation and surface climate in the Euro-Atlantic and Asian regions. In addition, our findings suggest that fully coupled ocean-atmosphere-sea ice models are likely necessary to study linkages between Arctic sea ice and midlatitudes, by better representing the interactions and feedbacks between the different components of the climate system.

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Benefits of sea ice initialization for the interannual-to-decadal climate prediction skill in the Arctic in EC-Earth3

Cited by 8 publications

References 64 publications

Reassessing seasonal sea ice predictability of the Pacific-Arctic sector using a Markov model

Reassessing seasonal sea ice predictability of the Pacific-Arctic sector using a Markov model

Lasting impact of winds on Arctic sea ice through the ocean's memory

Added value of assimilating springtime Arctic sea ice concentration in summer-fall climate predictions

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