Impact of North Atlantic SST and Jet Stream anomalies on European Heat Waves

European heat waves have increased during the two recent decades. Particularly 2015 and 2018 were characterized by a widespread area of cold North Atlantic sea surface temperatures (SSTs) in early summer as well as positive surface temperature anomalies across large parts of the European continent d...

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Main Authors:	Krüger, Julian, Pilch Kedzierski, Robin, Bumke, Karl, Matthes, Katja
Format:	Text
Language:	English
Published:	2020
Subjects:	North Atlantic
Online Access:	https://doi.org/10.5194/wcd-2020-32 https://wcd.copernicus.org/preprints/wcd-2020-32/

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spelling	ftcopernicus:oai:publications.copernicus.org:wcdd87116 2023-05-15T17:25:34+02:00 Impact of North Atlantic SST and Jet Stream anomalies on European Heat Waves Krüger, Julian Pilch Kedzierski, Robin Bumke, Karl Matthes, Katja 2020-08-07 application/pdf https://doi.org/10.5194/wcd-2020-32 https://wcd.copernicus.org/preprints/wcd-2020-32/ eng eng doi:10.5194/wcd-2020-32 https://wcd.copernicus.org/preprints/wcd-2020-32/ eISSN: 2698-4016 Text 2020 ftcopernicus https://doi.org/10.5194/wcd-2020-32 2020-08-10T16:22:00Z European heat waves have increased during the two recent decades. Particularly 2015 and 2018 were characterized by a widespread area of cold North Atlantic sea surface temperatures (SSTs) in early summer as well as positive surface temperature anomalies across large parts of the European continent during later summer. The European heat wave of 2018 is further suggested to be induced by a quasi-stationary and high-amplified Rossby wave pattern associated with the so-called quasi-resonant amplification (QRA) mechanism. In this study, we evaluate the North Atlantic SST anomalies and the QRA theory as potential drivers for European heat waves for the first time in combination by using the ERA-5 reanalysis product. A composite and correlation study reveals that cold North Atlantic SST anomalies in early summer favour a more undulating jet stream and a preferred trough-ridge pattern in the North Atlantic–European sector. Further we found that cold North Atlantic SSTs promote a stronger double jet occurrence in this sector. Thus, favorite conditions for a QRA signature are evident together with a necessary preconditioning of a double jet. However, our wave analysis covering two-dimensional probability density distributions of phase speed and amplitude does not confirm a relationship between cold North Atlantic SSTs and the QRA theory, compositing cold SSTs, high double jet indices (DJIs) or both together. Instead, we can show that cold North Atlantic SST events enhance the dominance of transient waves. In the presence of a trough during cold North Atlantic events, we obtain a slow-down of the transient waves, but not necessarily an amplification or stationarity. The deceleration of the transient waves result in a longer duration of a trough over the North Atlantic accompanied by a ridge downstream over Europe, triggering European heat episodes. Although a given DJI preconditioning may also be subject to the onset of certain QRA events, our study found no general relation between cold North Atlantic SST events and the QRA diagnostics. Our study highlights the relevance of cold North Atlantic SSTs for the onset of high European temperatures by affecting travelling jet stream undulations (but without involving QRA in general). Further attention should be drawn not only to the influence of North Atlantic SST year-to-year variability, but also to the effect of the North Atlantic warming hole as a negative SST anomaly in the long term, which is projected to evolve through climate change. Text North Atlantic Copernicus Publications: E-Journals
institution	Open Polar
collection	Copernicus Publications: E-Journals
op_collection_id	ftcopernicus
language	English
description	European heat waves have increased during the two recent decades. Particularly 2015 and 2018 were characterized by a widespread area of cold North Atlantic sea surface temperatures (SSTs) in early summer as well as positive surface temperature anomalies across large parts of the European continent during later summer. The European heat wave of 2018 is further suggested to be induced by a quasi-stationary and high-amplified Rossby wave pattern associated with the so-called quasi-resonant amplification (QRA) mechanism. In this study, we evaluate the North Atlantic SST anomalies and the QRA theory as potential drivers for European heat waves for the first time in combination by using the ERA-5 reanalysis product. A composite and correlation study reveals that cold North Atlantic SST anomalies in early summer favour a more undulating jet stream and a preferred trough-ridge pattern in the North Atlantic–European sector. Further we found that cold North Atlantic SSTs promote a stronger double jet occurrence in this sector. Thus, favorite conditions for a QRA signature are evident together with a necessary preconditioning of a double jet. However, our wave analysis covering two-dimensional probability density distributions of phase speed and amplitude does not confirm a relationship between cold North Atlantic SSTs and the QRA theory, compositing cold SSTs, high double jet indices (DJIs) or both together. Instead, we can show that cold North Atlantic SST events enhance the dominance of transient waves. In the presence of a trough during cold North Atlantic events, we obtain a slow-down of the transient waves, but not necessarily an amplification or stationarity. The deceleration of the transient waves result in a longer duration of a trough over the North Atlantic accompanied by a ridge downstream over Europe, triggering European heat episodes. Although a given DJI preconditioning may also be subject to the onset of certain QRA events, our study found no general relation between cold North Atlantic SST events and the QRA diagnostics. Our study highlights the relevance of cold North Atlantic SSTs for the onset of high European temperatures by affecting travelling jet stream undulations (but without involving QRA in general). Further attention should be drawn not only to the influence of North Atlantic SST year-to-year variability, but also to the effect of the North Atlantic warming hole as a negative SST anomaly in the long term, which is projected to evolve through climate change.
format	Text
author	Krüger, Julian Pilch Kedzierski, Robin Bumke, Karl Matthes, Katja
spellingShingle	Krüger, Julian Pilch Kedzierski, Robin Bumke, Karl Matthes, Katja Impact of North Atlantic SST and Jet Stream anomalies on European Heat Waves
author_facet	Krüger, Julian Pilch Kedzierski, Robin Bumke, Karl Matthes, Katja
author_sort	Krüger, Julian
title	Impact of North Atlantic SST and Jet Stream anomalies on European Heat Waves
title_short	Impact of North Atlantic SST and Jet Stream anomalies on European Heat Waves
title_full	Impact of North Atlantic SST and Jet Stream anomalies on European Heat Waves
title_fullStr	Impact of North Atlantic SST and Jet Stream anomalies on European Heat Waves
title_full_unstemmed	Impact of North Atlantic SST and Jet Stream anomalies on European Heat Waves
title_sort	impact of north atlantic sst and jet stream anomalies on european heat waves
publishDate	2020
url	https://doi.org/10.5194/wcd-2020-32 https://wcd.copernicus.org/preprints/wcd-2020-32/
genre	North Atlantic
genre_facet	North Atlantic
op_source	eISSN: 2698-4016
op_relation	doi:10.5194/wcd-2020-32 https://wcd.copernicus.org/preprints/wcd-2020-32/
op_doi	https://doi.org/10.5194/wcd-2020-32
_version_	1766117041058611200

Impact of North Atlantic SST and Jet Stream anomalies on European Heat Waves

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