Abstract
AbstractAtmospheric circulation is often clustered in so‐called circulation regimes, which are persistent and recurrent patterns. For the Euro‐Atlantic sector in winter, most studies identify four regimes: the Atlantic Ridge, Scandinavian Blocking and the two phases of the North Atlantic Oscillation. These results are obtained by applying k‐means clustering to the first several empirical orthogonal functions (EOFs) of geopotential height data. Studying the observed circulation in reanalysis data, it is found that when the full field data are used for the k‐means cluster analysis instead of the EOFs, the optimal number of clusters is no longer four but six. The two extra regimes that are found are the opposites of the Atlantic Ridge and Scandinavian Blocking, meaning they have a low‐pressure area roughly where the original regimes have a high‐pressure area. This introduces an appealing symmetry in the clustering result. Incorporating a weak persistence constraint in the clustering procedure is found to lead to a longer duration of regimes, extending beyond the synoptic time‐scale, without changing their occurrence rates. This is in contrast to the commonly used application of a time‐filter to the data before the clustering is executed, which, while increasing the persistence, changes the occurrence rates of the regimes. We conclude that applying a persistence constraint within the clustering procedure is a better way of stabilizing the clustering results than low‐pass filtering the data.
Highlights
The study of atmospheric circulation, or weather, regimes has a long history
We study the effect of time-filtering on the found regimes by comparing it with an adapted k-means clustering algorithm that incorporates a constraint on the regime duration to enforce persistence of the regimes
In this study we have shown, using an information criterion and further arguments based on the consistency of the clustering result, that the traditional number of four clusters is not optimal for representing wintertime Euro-Atlantic weather regimes when full field data is used
Summary
The study of atmospheric circulation, or weather, regimes has a long history. Starting from the 1940s, when the German weather service developed a set of weather types classifying the daily synoptic circulation (Deutscher Wetterdienst, 2019), the concept of weather regimes as an expression of the low-frequency variability of the atmospheric circulation has been a topic of research. Mo and Ghil, 1987; Vautard, 1990; Molteni et al, 1990), primarily focussing on the wintertime Northern Hemisphere. Later specific sectors of the Northern Hemisphere, primarily the Euro-Atlantic sector Mo, 2000) have been studied, along with the relation of circulation regimes with e.g. climate change (Corti et al., 1999) and regional weather (Cassou et al, 2005). More limited areas have been considered (e.g. Robertson and Ghil, 1999)
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