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dc.contributor.authorDella Chiesa S
dc.contributor.authorBertoldi G
dc.contributor.authorNiedrist G
dc.contributor.authorObojes N
dc.contributor.authorEndrizzi S
dc.contributor.authorAlbertson JD
dc.contributor.authorWohlfahrt G
dc.contributor.authorHortnagl L
dc.contributor.authorTappeiner U
dc.date.accessioned2018-09-27T12:26:58Z
dc.date.available2018-09-27T12:26:58Z
dc.date.issued2014
dc.identifier.issn1936-0584
dc.identifier.urihttp://dx.doi.org/10.1002/eco.1471
dc.identifier.urihttp://hdl.handle.net/10863/6115
dc.description.abstractThe effects of elevation on surface water fluxes in dry alpine grassland ecosystems were investigated along an elevational transect between 1000 and 2000m above sea level established in the Vinschgau/Venosta valley, a relatively dry region in the Italian Alps. The GEOtop-dv hydrological model was employed in point-scale mode to model the effects of the elevation gradient on snow water equivalent (SWE), soil water content (), evapotranspiration (ET), aboveground biomass (B-ag) and water use efficiency (WUE) in different climatic conditions. Results show that SWE decreased strongly with decreasing elevation but was also affected by the interannual variability of meteorological drivers. During warmer years, the magnitude of changes in SWE was mitigated at higher altitudes while exacerbated below 1500m. dynamics indicated that water stress conditions for vegetation currently occur at 1000m each year, while only a warmer and drier year caused drought at 1500m, and no water stress was found at 2000m.ET, B-ag and WUE did not decrease with elevation but showed a maximum at an intermediate elevation around 1500m because of the contrasting trends of a shorter vegetation season at higher elevations and water stress at lower elevations, where, in fact, irrigation is needed to maintain grassland productivity. A simulation based on long-term climatic conditions in combination with a sensitivity analysis of precipitation change showed that this effect is more pronounced during drier years, while for the wettest years, ET tended to decrease with increasing elevation. Taking these findings together, this study suggests that in relatively dry climatic conditions, mountain areas generally act as water towers' above 1500m. Quantifying this critical threshold and its likely future variation under climate change scenarios is a challenge for water resource research in the Alpine region and can help stakeholders in planning future mitigation strategies.en_US
dc.language.isoenen_US
dc.rights
dc.titleModelling changes in grassland hydrological cycling along an elevational gradient in the Alpsen_US
dc.typeArticleen_US
dc.date.updated2018-09-27T12:24:37Z
dc.language.isiEN-GB
dc.journal.titleEcohydrology
dc.description.fulltextnoneen_US


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