| Summary: | Persistent weather patterns are responsible for much of the extreme weather experienced around the world. These persistent patterns have also been found to reoccur over certain regions including the Eastern Pacic, North America, Europe, and the North Atlantic. We term these persistent, reoccurring patterns "circulation regimes". In this thesis we focus on regimes in the Euro-Atlantic region. Circulation Regimes provide a single consistent framework to describe large-scale patterns in the Euro-Atlantic (EA) region such as the North Atlantic Oscillation (NAO) and European Blocking. Each individual state of the atmosphere is uniquely associated with one regime, and each regime is accompanied by distinct weather patterns, and likelihoods of extreme events. This thesis focuses on transitions between four EA regimes and precursors of such transitions. We examine the signature of tropical heating preceding transitions between each type of regime transition and identify transitions for which this forcing plays a role. We further examine the relationship of heating to the Madden-Julian Oscillation (MJO), the El-Nino Southern Oscillation, and shifts in the intertropical Convergence Zone (ITCZ). Mid-latitude diabatic heating is examined to determine shifts in the storm tracks. We use the ERA-Interim reanalysis (at full horizontal resolution, 6 hourly) to estimate the diabatic heating as a residual in the thermodynamic equation. The same reanalysis is used to perform a k-means cluster analysis of 500 hPa geopotential height in the EA region during boreal winter, yielding the regimes of NAO+, NAO-, Scandinavian Blocking and Atlantic Ridge. We composite the vertically integrated, planetary wave diabatic heating, 300 hPa streamfunction, and Rossby wave activity. We nd that the effects of Indian Ocean tropical heating are to enhance the transition from the Scandinavian Blocking EA circulation regime to the NAO+ regime, while western Pacic heating seems to force transitions from all other regimes into the NAO- regime. The flux ...
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