Abstract

Abstract. Sudden stratospheric warming (SSW) events can significantly impact tropospheric weather for a period of several weeks, in particular in the North Atlantic–European (NAE) region. While the stratospheric forcing often projects onto the North Atlantic Oscillation (NAO), the tropospheric response to SSW events, if any, is highly variable, and what determines the existence, location, timing, and strength of the downward impact remains an open question. We here explore how the variable tropospheric response to SSW events in the NAE region can be characterized in terms of a refined set of seven weather regimes and if the tropospheric flow in the North Atlantic region around the onset of SSW events is an indicator of the subsequent downward impact. The weather regime analysis reveals the Greenland blocking (GL) and Atlantic trough (AT) regimes as the most frequent large-scale patterns in the weeks following an SSW. While the GL regime is dominated by high pressure over Greenland, AT is dominated by a southeastward-shifted storm track in the North Atlantic. The flow evolution associated with GL and the associated cold conditions over Europe in the weeks following an SSW occur most frequently if a blocking situation over western Europe and the North Sea (European blocking) prevailed around the SSW onset. In contrast, an AT regime associated with mild conditions over Europe is more likely following the SSW event if GL occurs already around SSW onset. For the remaining tropospheric flow regimes during SSW onset we cannot identify a dominant flow evolution. Although it remains unclear what causes these relationships, the results suggest that specific tropospheric states in the days around the onset of the SSW are an indicator of the subsequent tropospheric flow evolution in the aftermath of an SSW, which could provide crucial guidance for subseasonal prediction.

Highlights

  • Sudden stratospheric warming (SSW) events can have a significant impact on the tropospheric large-scale circulation and on surface weather (Baldwin and Dunkerton, 2001)

  • Our conclusions are as follows: 1. In the aftermath of an SSW event, the tropospheric flow in the North Atlantic–European (NAE) region exhibits an evolution that is unlikely to occur in the absence of an SSW

  • Positive geopotential height anomalies related to Greenland blocking are statistically more likely to occur after the onset of the SSW than in the absence of an SSW

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Summary

Introduction

Sudden stratospheric warming (SSW) events can have a significant impact on the tropospheric large-scale circulation and on surface weather (Baldwin and Dunkerton, 2001). Recent work revealed important shifts of regime occurrence and transition probabilities between regimes on subseasonal timescales of several weeks depending on the external forcing such as the stratospheric polar vortex state (Charlton-Perez et al, 2018; Papritz and Grams, 2018; Beerli and Grams, 2019). This motivates the study at hand aiming at investigating if the variability in the tropospheric flow evolution following SSW events can be characterized in terms of the weather regime around the SSW onset

Data and classifications
Statistical testing
Weather regimes during SSW events
Temporal evolution of the downward impact
Impact on surface weather
Findings
Summary and discussion

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