Attribution of precipitation to cyclones and fronts over Europe  in a kilometer-scale regional climate simulation

Rüdisühli, Stefan; Sprenger, Michael; Leutwyler, David; Schär, Christoph; Wernli, Heini

doi:10.5194/wcd-1-675-2020

Cited by 24 publications

(21 citation statements)

References 76 publications

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“…Therefore, as we follow the typical displacement of an Atlantic front on its way to the IP from west to east, we find progressively more negative winter δ 18 O p values (see values for January-February-March in Table 2) going from El Pindal (−6.0 ‰), to Ortigosa de Cameros (−8.1 ‰) to Borrastre (−9.8 ‰) and, finally, to Molinos (−10.0 ‰). This pattern is not as evident in other seasons when the entrance of Atlantic fronts is not the dominant synoptic situation that generates rainfall in the transect (Rüdisühli et al, 2020). In addition to this continental effect, which accounts for only a small gradient in δ 18 O p (about 0.002 ‰ km −1 in Europe as described in Rozanski et al, 1993), the higher annual mean air temperature in both Mallorca and Barcelona as well as Oviedo and El Pindal compared to the other stations (Table 1), may help explain their similar δ 18 O p values.…”

Section: Geographical Controls On Rainfall Isotopic Variabilitymentioning

confidence: 85%

“…In northwestern and north-central Iberia, precipitation is mainly controlled by the presence of westerly winds and the passage of Atlantic fronts, especially during November-April (Martín-Vide and Olcina Cantos, 2001;Rüdisühli et al, 2020). During the rest of the year, the subtropical Azores high-pressure system shifts northward, which blocks the westerly circulation and moisture inflow from Atlantic sources (Archer and Caldeira, 2008), thus favoring stable atmospheric conditions and reducing precipitation.…”

Section: Weather Regime Climate and Site Descriptionmentioning

confidence: 99%

“…The role of geographic factors (continental and elevation effects) and atmospheric processes (moisture origin and type of rainfall) is evaluated. Additionally, this study will serve to improve the interpretation of oxygen isotope paleorecords from the northern IP that depend on δ 18 O p (Bartolomé et al, 2015;Domínguez-Villar et al, 2017;López-Blanco et al, 2016;Pérez-Mejías et al, 2019;Sancho et al, 2018Sancho et al, , 2015.…”

Section: Introductionmentioning

confidence: 99%

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Measurement report: Spatial variability of northern Iberian rainfall stable isotope values – investigating atmospheric controls on daily and monthly timescales

et al. 2021

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Abstract. For the first time, this article presents a large dataset of precipitation isotopic measurements (δ18Op and δ2Hp) sampled every day or 2 d from seven sites on a west-to-east transect across northern Spain for 2010–2017. The main aim of this study is to (1) characterize the rainfall isotopic variability in northern Spain at daily and monthly timescales and (2) assess the principal factors influencing rainfall isotopic variability. The relative role of air temperature and rainfall in determining the stable isotope composition of precipitation changes along the west-to-east transect, with air temperature being highly correlated with δ18Op at daily and monthly timescales, while a few sites along the transect show a significant negative correlation with precipitation. The highest air temperature–δ18Op dependency is found for a station located in the Pyrenees. Frontal systems associated with North Atlantic cyclones are the dominant mechanism inducing precipitation in this region, particularly in winter. This study allows an exploration of the role of air mass source and trajectory in determining the isotopic composition of rainfall in northern Iberia by characterizing the moisture uptake for three of the seven stations. The importance of continental versus marine moisture sources is evident, with clear seasonal and spatial variations. In addition, the type of precipitation (convective versus frontal rainfall) plays a key role, with convective rainfall associated with higher δ18Op values. This comprehensive spatiotemporal approach to analyzing the rainfall isotopic composition represents another step forward towards developing a more detailed, mechanistic framework for interpreting stable isotopes in rainfall as a paleoclimate and hydrological tracer.

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Section: Geographical Controls On Rainfall Isotopic Variabilitymentioning

confidence: 85%

Section: Weather Regime Climate and Site Descriptionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Measurement report: Spatial variability of northern Iberian rainfall stable isotope values – investigating atmospheric controls on daily and monthly timescales

et al. 2021

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“…This way, the size of the data to handle reduces dramatically from 3D fields (horizontal spatial dimension and time) to a few parameters of interest, without the loss of relevant information. As an interesting application of the tracking approach, Rüdisühli et al (2020) analyzed the climatological distribution of precipitation in Europe in relation to cyclones and fronts in a 9-year European CPRCM simulation. Finally, a classification algorithm has been proposed to identify days with an elevated potential for extreme precipitation, or other variables for which added value is expected, in order to perform CPRCM simulations only when they are deemed the most useful, reducing the computational load (Beaulant et al, 2011;Meredith et al, 2018).…”

Section: Alternative Strategies To Optimize Cprcm Evaluationmentioning

confidence: 99%

Convection‐permitting modeling with regional climate models: Latest developments and next steps

Lucas‐Picher

Argüeso

Brisson

et al. 2021

WIREs Climate Change

133

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Approximately 10 years ago, convection-permitting regional climate models (CPRCMs) emerged as a promising computationally affordable tool to produce fine resolution (1-4 km) decadal-long climate simulations with explicitly resolved deep convection. This explicit representation is expected to reduce climate projection uncertainty related to deep convection parameterizations found in most climate models. A recent surge in CPRCM decadal simulations over larger domains, sometimes covering continents, has led to important insights into CPRCM advantages and limitations. Furthermore, new observational gridded datasets with fine spatial and temporal ($1 km; $1 h) resolutions have leveraged additional knowledge through evaluations of the added value of CPRCMs. With an improved coordination in the frame of ongoing international initiatives, the production of ensembles of CPRCM simulations is expected to provide more robust climate projections and a better identification of their associated uncertainties. This review paper presents an overview of the methodology to produce CPRCM simulations and the latest research on the related added value in current and future climates. Impact studies that are already taking advantage of these new CPRCM simulations are highlighted. This review paper ends by proposing next steps that could be accomplished to continue exploiting the full potential of CPRCMs.

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“…For instance, the west coast of the US, the Iberian Peninsula and the north African coast, as well as Chile and eastern Australia, all experience primary extreme wet seasons in winter. This suggests that such regions are influenced by systems that made landfall, such as extratropical cyclones 76 E. Flaounas et al: Extreme wet seasons -their definition and relationship with synoptic-scale weather systems and atmospheric rivers (Rutllant and Fuenzalida, 1991;Leung and Qian, 2009;Lavender and Abbs, 2012;Flaounas et al, 2017). Other exceptions from the dominant summer occurrence of extreme wet seasons over land are several regions in the Northern Hemisphere where extreme seasons occur in spring, in contrast to summer for their neighboring continental areas.…”

Section: Rossby Wave Breakingmentioning

confidence: 99%

Extreme wet seasons – their definition and relationship with synoptic-scale weather systems

Flaounas

Röthlisberger

Boettcher

et al. 2021

Weather Clim. Dynam.

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Abstract. An extreme aggregation of precipitation on the seasonal timescale, leading to a so-called extreme wet season, can have substantial environmental and socio-economic impacts. This study has a twofold aim: first to identify and statistically characterize extreme wet seasons around the globe and second to elucidate their relationship with specific weather systems. Extreme wet seasons are defined independently at every grid point of ERA-Interim reanalyses as the consecutive 90 d period with the highest accumulated precipitation in the 40-year period of 1979–2018. In most continental regions, the extreme seasons occur during the warm months of the year, especially in the midlatitudes. Nevertheless, colder periods might be also relevant, especially in coastal areas. All identified extreme seasons are statistically characterized in terms of climatological anomalies of the number of wet days and of daily extreme events. Results show that daily extremes are decisive for the occurrence of extreme wet seasons in regions of frequent precipitation, e.g., in the tropics. This is in contrast to arid regions where wet seasons may occur only due to anomalously frequent wet days. In the subtropics and more precisely within the transitional zones between arid areas and regions of frequent precipitation, both an anomalously high occurrence of daily extremes and of wet days are related to the formation of extreme wet seasons. A novel method is introduced to define the spatial extent of regions affected by a particular extreme wet season and to relate extreme seasons to four objectively identified synoptic-scale weather systems, which are known to be associated with intense precipitation: cyclones, warm conveyor belts, tropical moisture exports and breaking Rossby waves. Cyclones and warm conveyor belts contribute particularly strongly to extreme wet seasons in most regions of the globe. But interlatitudinal influences are also shown to be important: tropical moisture exports, i.e., the poleward transport of tropical moisture, can contribute to extreme wet seasons in the midlatitudes, while breaking Rossby waves, i.e., the equatorward intrusion of stratospheric air, may decisively contribute to the formation of extreme wet seasons in the tropics. Three illustrative examples provide insight into the synergetic effects of the four identified weather systems on the formation of extreme wet seasons in the midlatitudes, the Arctic and the (sub)tropics.

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Attribution of precipitation to cyclones and fronts over Europe in a kilometer-scale regional climate simulation

Cited by 24 publications

References 76 publications

Measurement report: Spatial variability of northern Iberian rainfall stable isotope values – investigating atmospheric controls on daily and monthly timescales

Measurement report: Spatial variability of northern Iberian rainfall stable isotope values – investigating atmospheric controls on daily and monthly timescales

Convection‐permitting modeling with regional climate models: Latest developments and next steps

Extreme wet seasons – their definition and relationship with synoptic-scale weather systems

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