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4. Impacts and damages of the European multi-year drought and heat event 2018–2022 on forests, a review.

Author

Knutzen, Florian, Averbeck, Paul, Barrasso, Caterina, Bouwer, Laurens M., Gardiner, Barry, Grünzweig, José M., Hänel, Sabine, Haustein, Karsten, Johannessen, Marius Rohde, Kollet, Stefan, Pietikaeinen, Joni-Pekka, Pietras-Couffignal, Karolina, Pinto, Joaquim G., Rechid, Diana, Rousi, Efi, Russo, Ana, Suarez-Gutierrez, Laura, Wendler, Julian, Xoplaki, Elena, and Gliksman, Daniel

Subjects
DROUGHT management, DROUGHTS, HEAT adaptation, CLIMATE change, FOREST fires
Abstract

Drought and heat events are becoming more frequent in Europe due to human-induced climate change, affecting many aspects of human well-being and ecosystem functioning. However, the intensity of these drought and heat events is not spatially and temporally uniform. Understanding the spatial variability of drought impacts is important information for decision makers, supporting both planning and preparations to cope with the changing climatic conditions. Currently, data relating to the damage caused by extended drought episodes is scattered across languages and sources such as scientific publications, governmental reports and the media. In this review paper, we compiled data of damages caused by the drought and heat of 2018 until 2022 in forest ecosystems and relate it to large European data sets, providing support for decision making both on the regional and European levels. We partitioned data from 16 European countries to the following regions: Northern, Central, Alpine, and South. We focused on drought and heat damage to forests, and categorized them as (1) physiological (2) pest, and (3) fire damage. We were able to identify the following key trends: (1) Relative defoliation rates of broadleaves is higher than of conifers in every country with the exception of Czech Republic (2) the incidence of wood destroyed by insects is extremely high in Central Europe and Sweden (3) Although forest fires can be related to heat and drought, they are superimposed by other anthropogenic influences (4) In this period (2018–2022), forests in central Europe are particularly affected, while forests in the Northern and Alpine zones are less affected, and adaptations to heat and drought can still be observed in the Southern zone. (5) Although in several regions 2021 was an average year still high levels of damages were observed indicating strong legacy effects of 2018–2020. We note that the inventory should be continuously updated as new data appear. [ABSTRACT FROM AUTHOR]

Published
2023
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5. The extremely hot and dry 2018 summer in central and northern Europe from a multi-faceted weather and climate perspective.

Author

Rousi, Efi, Fink, Andreas H., Andersen, Lauren S., Becker, Florian N., Beobide-Arsuaga, Goratz, Breil, Marcus, Cozzi, Giacomo, Heinke, Jens, Jach, Lisa, Niermann, Deborah, Petrovic, Dragan, Richling, Andy, Riebold, Johannes, Steidl, Stella, Suarez-Gutierrez, Laura, Tradowsky, Jordis S., Coumou, Dim, Düsterhus, André, Ellsäßer, Florian, and Fragkoulidis, Georgios

Subjects
DROUGHTS, HEAT waves (Meteorology), ATMOSPHERIC circulation, NORTH Atlantic oscillation, EFFECT of human beings on climate change, WEATHER, AIR masses
Abstract

The summer of 2018 was an extraordinary season in climatological terms for northern and central Europe, bringing simultaneous, widespread, and concurrent heat and drought extremes in large parts of the continent with extensive impacts on agriculture, forests, water supply, and the socio-economic sector. Here, we present a comprehensive, multi-faceted analysis of the 2018 extreme summer in terms of heat and drought in central and northern Europe, with a particular focus on Germany. The heatwave first affected Scandinavia in mid-July and shifted towards central Europe in late July, while Iberia was primarily affected in early August. The atmospheric circulation was characterized by strongly positive blocking anomalies over Europe, in combination with a positive summer North Atlantic Oscillation and a double jet stream configuration before the initiation of the heatwave. In terms of possible precursors common to previous European heatwaves, the Eurasian double-jet structure and a tripolar sea surface temperature anomaly over the North Atlantic were already identified in spring. While in the early stages over Scandinavia the air masses at mid and upper levels were often of a remote, maritime origin, at later stages over Iberia the air masses primarily had a local-to-regional origin. The drought affected Germany the most, starting with warmer than average conditions in spring, associated with enhanced latent heat release that initiated a severe depletion of soil moisture. During summer, a continued precipitation deficit exacerbated the problem, leading to hydrological and agricultural drought. A probabilistic attribution assessment of the heatwave in Germany showed that such events of prolonged heat have become more likely due to anthropogenic global warming. Regarding future projections, an extreme summer such as that of 2018 is expected to occur every 2 out of 3 years in Europe in a + 1.5 ∘ C warmer world and virtually every single year in a + 2 ∘ C warmer world. With such large-scale and impactful extreme events becoming more frequent and intense under anthropogenic climate change, comprehensive and multi-faceted studies like the one presented here quantify the multitude of their effects and provide valuable information as a basis for adaptation and mitigation strategies. [ABSTRACT FROM AUTHOR]

Published
2023
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6. The extremely hot and dry 2018 summer in central and northern Europe from a multi-faceted weather and climate perspective.

Author

Rousi, Efi, Fink, Andreas H., Andersen, Lauren S., Becker, Florian N., Beobide-Arsuaga, Goratz, Breil, Marcus, Cozzi, Giacomo, Heinke, Jens, Jach, Lisa, Niermann, Deborah, Petrovic, Dragan, Richling, Andy, Riebold, Johannes, Steidl, Stella, Suarez-Gutierrez, Laura, Tradowsky, Jordis, Coumou, Dim, Düsterhus, André, Ellsäßer, Florian, and Fragkoulidis, Georgios

Subjects
DROUGHTS, ATMOSPHERIC circulation, NORTH Atlantic oscillation, GLOBAL warming
Abstract

The summer of 2018 was an extraordinary season in climatological terms for northern and central Europe, bringing simultaneous, widespread, and concurrent heat and drought extremes in large parts of the continent with extensive impacts on agriculture, forests, water supply, and socio-economic sector. We present a comprehensive, multi-faceted analysis of the 2018 extreme summer in terms of heat and drought in central and northern Europe with a particular focus on Germany. The heatwave first affected Scandinavia by mid-July, shifted towards central Europe in late July, while Iberia was primarily affected in early August. The atmospheric circulation was characterized by strongly positive blocking anomalies over Europe, in combination with a positive summer North Atlantic Oscillation and a double jet stream configuration before the initiation of the heatwave. In terms of possible precursors common to previous European heatwaves, the Eurasian double jet structure and a tripolar sea-surface temperature anomaly over the North Atlantic were identified already in spring. While in the early stages over Scandinavia the air masses at mid- and upper-levels were often of remote, maritime origin, at later stages over Iberia the air masses had primarily a local to regional origin. The drought affected Germany the most, starting with warmer than average conditions in spring, associated with enhanced latent heat release that initiated a severe depletion of soil moisture. During summer, a continued precipitation deficit exacerbated the problem, leading to hydrological and agricultural drought. A probabilistic attribution assessment of the heatwave in Germany showed that the prolonged heat has become more likely due to global warming. Regarding future projections, an extreme summer such as this of 2018 is expected to occur every two out of three years in Europe under a 1.5 °C warmer world and virtually every single year under 2 °C of global warming. With such large-scale and impactful extreme events becoming more frequent and intense under anthropogenic climate change, comprehensive and multi-faceted studies like the one presented here quantify the multitude of effects and provide valuable information as basis for adaptation and mitigation strategies. [ABSTRACT FROM AUTHOR]

Published
2022
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7. Circumglobal Rossby wave patterns during boreal winter highlighted by space–time spectral analysis.

Author

Riboldi, Jacopo, Rousi, Efi, D'Andrea, Fabio, Rivière, Gwendal, and Lott, François

Subjects
ROSSBY waves, WAVENUMBER, TROPOSPHERE, MULTIPLE correspondence analysis (Statistics), WAVE packets
Abstract

The classic partitioning between slow-moving, low-wavenumber planetary waves and fast-moving, high-wavenumber synoptic waves is systematically extended by means of a space–time spectral decomposition to characterize the day-to-day evolution of Rossby wave activity in the upper troposphere. This technique is employed to study the origin and the propagation of circumglobal Rossby wave patterns (CRWPs), amplified Rossby waves stretching across the Northern Hemisphere in the zonal direction and projecting primarily over few, dominant wavenumber–phase-speed harmonics. Principal component analysis of daily anomalies in spectral power allows for two CRWPs to emerge as leading variability modes in the spectral domain during boreal winter. These modes correspond to the baroclinic propagation of Rossby wave packets (RWPs) from the Pacific to the Atlantic storm track in a hemispheric flow configuration displaying enhanced meridional gradients of geopotential height over midlatitudes. The first CRWP is forced by tropical convection anomalies over the Indian Ocean and features the propagation of amplified RWPs over northern midlatitudes, while the second one propagates rapidly over latitudes between 35 and 55 ∘ N and appears to have extratropical origin. An anomalous equatorward propagation of Rossby waves from the Atlantic eddy-driven jet to the North African subtropical jet is observed for both CRWPs. The obtained results highlight the substantial contribution of propagating RWPs to CRWPs, hinting that the two features might have the same nature. [ABSTRACT FROM AUTHOR]

Published
2022
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8. Implications of Winter NAO Flavors on Present and Future European Climate.

Author

Rousi, Efi, Rust, Henning W., Ulbrich, Uwe, and Anagnostopoulou, Christina

Subjects
NORTH Atlantic oscillation, PRECIPITATION anomalies, FLAVOR, SELF-organizing maps, CLIMATOLOGY
Abstract

The North Atlantic Oscillation (NAO), a basic variability mode in the Northern Hemisphere, undergoes changes in its temporal and spatial characteristics, with significant implications on European climate. In this paper, different NAO flavors are distinguished for winter in simulations of a Coupled Atmosphere-Ocean GCM, using Self-Organizing Maps, a topology preserving clustering algorithm. These flavors refer to various sub-forms of the NAO pattern, reflecting the range of positions occupied by its action centers, the Icelandic Low and the Azores High. After having defined the NAO flavors, composites of winter temperature and precipitation over Europe are created for each one of them. The results reveal significant differences between NAO flavors in terms of their effects on the European climate. Generally, the eastwardly shifted NAO patterns induce a stronger than average influence on European temperatures. In contrast, the effects of NAO flavors on European precipitation anomalies are less coherent, with various areas responding differently. These results confirm that not only the temporal, but also the spatial variability of NAO is important in regulating European climate. [ABSTRACT FROM AUTHOR]

Published
2020
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9. Summer North Atlantic SST and atmospheric circulation patterns in a changing climate.

Author

Rousi, Efi, Coumou, Dim, Rahmstorf, Stephan, and Griffies, Stephen

Subjects
*ATMOSPHERIC circulation, *GEOPHYSICAL fluid dynamics, *CLIMATE change, *MERIDIONAL overturning circulation, *GEOPOTENTIAL height, *CLIMATE extremes
Abstract

North Atlantic oceanic and atmospheric variability is central in determining the behavior of surface climate and hence the occurrence of extremes over the Northern Hemisphere, which in turn have huge impacts on societies, economies and environment. The aim of this study is to gain further insight on the evolution of SST and atmospheric circulation patterns in the context of a changing climate.We use the CM2.6 model, which is the latest version of a series of high-resolution global coupled climate models developed by the NOAA Geophysical Fluid Dynamics Laboratory, with a horizontal resolution of 0.1° (roughly equal to 10km) in the ocean, and a coarser resolution of 0.5°in the atmosphere (50km). Two 80-year long experiments are used, a control simulation with constant pre-industrial atmospheric CO2 concentrations (CR) and a run with CO2 increasing 1% per year until doubling in year 70 and held constant thereafter (2xCO2). We apply Self-Organizing Maps (SOMs), a topology preserving clustering algorithm, to obtain SST and geopotential height (gph500) patterns and we evaluate the model against observations and reanalysis data. We find that the model reproduces the observed patterns very well, even with the use of an objective clustering technique.We then look at changes in frequency and persistence of the patterns in the 2xCO2 run. As expected, the SST response to the CO2 doubling is much more straightforward than the atmospheric response. However, there are patterns in both fields that differ in frequency and amplitude under a changing climate, along with some emerging patterns, which cannot be ordered in any of the CR clusters. Among the latter, a wave-like atmospheric pattern is found in summer months that resembles the one associated with severe heatwaves in Europe during the last decades. There are different possible causes behind those emergent atmospheric patterns under increasing CO2, among which the role of the Arctic Amplification and the slowdown of the Atlantic Meridional Overturning Circulation, that are both prominent in recent years and are common features in future scenarios. Both processes are linked to weakening westerlies in summer over the Atlantic sector, favoring quasi-stationary wave-trains and persistent hot-dry extremes over Europe. Those emerging atmospheric patterns will be further examined regarding their SST precursors and their composites of different climate parameters over Europe. [ABSTRACT FROM AUTHOR]

Published
2019

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