Daily gridded datasets of snow depth and snow water equivalent for the Iberian Peninsula from 1980 to 2014

Alonso‐González, Esteban; López‐Moreno, J. I.; Gascoin, Simon; Ojeda, Matilde García Valdecasas; Sanmiguel‐Vallelado, Alba; Navarro-Serrano, Francisco; Revuelto, Jesús; Ceballos, Antonio; Esteban‐Parra, María Jesús; Essery, Richard

doi:10.5194/essd-10-303-2018

Cited by 36 publications

(25 citation statements)

References 56 publications

Supporting

Mentioning

Contrasting

Unclassified

Order By: Relevance

“…Meteorological surface data was derived from the ERA-Interim reanalysis dynamically downscaled to 10 × 10 km resolution with the Weather Research and Forecasting model (WRF) by García-Valdecasas et al [34]. This was then coupled with a snow energy-balance simulation with Factorial Snow model (FSM), by Alonso-González et al [32]. They used the downscaled climate data to run the FSM and constructed a semi-distributed grid of daily snow depth (SD) and snow water equivalent (SWE) with 10 × 10 km resolution for the entire Iberian Peninsula spanning from 1980 to 2014.…”

Section: Datamentioning

confidence: 99%

“…They used the downscaled climate data to run the FSM and constructed a semi-distributed grid of daily snow depth (SD) and snow water equivalent (SWE) with 10 × 10 km resolution for the entire Iberian Peninsula spanning from 1980 to 2014. The grid was vertically rescaled to 100 m elevation bands using an array of radiative and psychrometric formulas and lapse rates (see details in [32]). Alonso-González et al [32] proved the consistency of the database with in situ SD and SWE observations and remote sensing data, accurately reproducing the temporal and spatial patterns of snow.…”

Section: Datamentioning

confidence: 99%

“…The grid was vertically rescaled to 100 m elevation bands using an array of radiative and psychrometric formulas and lapse rates (see details in [32]). Alonso-González et al [32] proved the consistency of the database with in situ SD and SWE observations and remote sensing data, accurately reproducing the temporal and spatial patterns of snow. For the purpose of our study, we extracted both, the downscaled climate data (3-hourly temperature, relative humidity and precipitation) and the daily SWE data corresponding to the extent of the 25 selected river watersheds.…”

Section: Datamentioning

confidence: 99%

“…This was thanks to techniques that allow a reasonable estimation of the quantity of water in the snowpack, including remote sensing and modeling approaches. On this regard, a new range of possibilities for research on snow hydrology in Spain was recently opened up with the publication of a gridded dataset of snow depth and snow water equivalent for Spain by Alonso-González et al [32].…”

Section: Introductionmentioning

confidence: 99%

“…Considering the abovementioned research gap and the new snow dataset for the Spanish mountains [32], the aim of this paper is to determine the main drivers of major floods in mountain rivers in Spain. Specifically, the objectives of the research are (1) to determine whether the major floods are derived from rain, snowmelt, or a combination of rain and snowmelt; (2) to quantify the relative contribution of each on the total flooding streamflow; (3) to explore the main characteristics of the floods hydrographs [27,28] according to the relative contribution of rainfall and snowmelt and (4) to determine whether the geographical characteristics of the catchments, and atmospheric circulation over the Iberian region can explain the relative importance of rainfall and snowmelt in triggering major floods.…”

Section: Introductionmentioning

confidence: 99%

See 4 more Smart Citations

Hydro-Meteorological Characterization of Major Floods in Spanish Mountain Rivers

Morán-Tejéda

Fassnacht

Lorenzo‐Lacruz

et al. 2019

Water

Self Cite

View full text Add to dashboard Cite

Spain, one of the most mountainous countries in Europe, suffers from frequent river flooding due to specific climatic and topographic features. Many headwaters of the largest rivers in Spain are located in mountainous areas of mid-to-high elevation. These include the Pyrenees, the Central System, and the Cantabrian mountains, that have a sustained snowpack during the winter months. Most previous research on flood generation in Spain has focused on intense rainfall events, and the role of snowmelt has been ignored or considered marginal. In this paper we present a regional-scale study to quantify the relative importance of rainfall versus snowmelt in the largest floods recorded in mountain rivers in Spain during the last decades (1980–2014). We further analyzed whether catchments characteristics and weather types may favor the occurrence of rainfall or snowmelt induced floods. Results show that in 53% of the 250 analyzed floods the contribution of rainfall was larger than 90%, and in the rest of events snowmelt contribution was larger than 10%. Floods where snowmelt was the main contributor represented only 5% of the total events. The average contribution of snowmelt represents 18% of total runoff in floods that were analyzed. The role of snowmelt in floods, rather than triggering the event, was usually amplifying the duration of the event, especially after the peak flow was reached. In general, the importance of snowmelt in floods is greater in catchments with characteristics that favor snow accumulation. However, this does not apply to floods where contribution of snowmelt was larger than 90%, which tend to occur at catchments at mid-elevations that accumulate unusual amounts of snow that melt rapidly. Floods were more frequent under both cyclonic and anticyclonic synoptic situations over the Iberian Peninsula, as well as under advection of western and eastern flows. Our results contribute to the ongoing improvement of knowledge about the role of snow in the hydrology of Spanish rivers and on the importance of mountain processes on the hydrology of downstream areas.

show abstract

Section: Datamentioning

confidence: 99%

Section: Datamentioning

confidence: 99%

Section: Datamentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

See 3 more Smart Citations

Hydro-Meteorological Characterization of Major Floods in Spanish Mountain Rivers

Morán-Tejéda

Fassnacht

Lorenzo‐Lacruz

et al. 2019

Water

Self Cite

View full text Add to dashboard Cite

show abstract

The role of meteorological forcing and snow model complexity in winter glacier mass balance estimation, Columbia River basin, Canada

Mortezapour¹,

Menounos²,

Jackson³

et al. 2020

Hydrological Processes

View full text Add to dashboard Cite

Glaciers are commonly located in mountainous terrain subject to highly variable meteorological conditions. High resolution meteorological (HRM) data simulated by atmospheric models can complement meteorological station observations in order to assess changes in glacier energy fluxes and mass balance. We examine the performance of two snow models, SnowModel and Alpine3D, forced by different meteorological data for winter mass balance simulations at four glaciers in the Canadian portion of the Columbia Basin. The Weather Research and Forecasting model (WRF) with resolution of 1 km and the North American Land Data Assimilation System with 12 km resolution, provide HRM data for the two snow models. Evaluation is based on the ability of the snow models to simulate snow depth at both point locations (automated snow weather stations) and over the entire glacier surface (airborne LiDAR [Light Detection and Ranging] surveys) during the 2015/2016 winter accumulation. When forced with HRM data, both models can reproduce snow depth to within ±15% of observed values. Both models underestimate winter mass balance when forced by HRM data. When driven with WRF data, SnowModel underestimates winter mass balance integrated over the glacier area by 1 and 10%, whilst Alpine3D underestimates winter mass balance by 12 and 22% compared with LiDAR and stake measurements, respectively. The overall results show that SnowModel forced by WRF simulated winter mass balance the best.

show abstract

Snow climatology for the mountains in the Iberian Peninsula using satellite imagery and simulations with dynamically downscaled reanalysis data

Alonso‐González

López‐Moreno

Navarro-Serrano

et al. 2019

Intl Journal of Climatology

View full text Add to dashboard Cite

The presence of a seasonal snowpack determines the hydrology, geomorphology and ecology of wide parts of the Iberian Peninsula, with strong implications for the economy, transport and risk management. Thus, reliable information on snow is necessary from a scientific and operational point of view. This is the case of the Iberian Peninsula where, lack of observation has impeded proper analysis of snowpack duration, magnitude and interannual variability. In this study, we present the first snow climatology of the entire Iberian Peninsula. The scarcity of in situ observations has been overcome, using a newly developed remote sensing snow database from MODIS satellite sensors for the period 2000–2014 and a physically based snow model (Factorial Snow Model—FSM), driven by a regional atmospheric model (Weather Research and Forecast model—WRF) over the Iberian Peninsula for the period 1980–2014. The snowpack of the main mountain areas (Pyrenees, Cantabrian, Central, Iberian range and Sierra Nevada) are described, estimated from the generated databases. The information has been processed using a k‐means cluster algorithm, looking for similarities in snow indices at different elevation bands. Results show four different types of snowpack in terms of depth, duration and interannual variability, lying over different elevation bands in the different ranges, proving the variability of the snowpack over Iberia. Analyses reveal areas characterized by ephemeral snowpacks, while in some sectors snowpack lasts, on average, 198 days per year with 3.02 m of peak snow depth. The coefficient of variation of interannual peak snow depth oscillated between 35.2 and 162.4%. All the analysed indices show that at common elevations the Cantabrian range and the Pyrenees host the deepest and longest lasting snowpacks, followed by the Central and Iberian ranges. The Sierra Nevada exhibits the shortest, shallowest snowpack and more year‐to‐year variability.

show abstract

Daily gridded datasets of snow depth and snow water equivalent for the Iberian Peninsula from 1980 to 2014

Cited by 36 publications

References 56 publications

Hydro-Meteorological Characterization of Major Floods in Spanish Mountain Rivers

Hydro-Meteorological Characterization of Major Floods in Spanish Mountain Rivers

The role of meteorological forcing and snow model complexity in winter glacier mass balance estimation, Columbia River basin, Canada

Snow climatology for the mountains in the Iberian Peninsula using satellite imagery and simulations with dynamically downscaled reanalysis data

Contact Info

Product

Resources

About