Spatial distribution of stable water isotopes in alpine snow cover

Dietermann, N.; Weiler, Markus

doi:10.5194/hess-17-2657-2013

Cited by 47 publications

(59 citation statements)

References 31 publications

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“…Moreover, snow samples plotted well on the LMWL (and therefore on the GMWL), as also confirmed by the slope and interception values very similar to those of the LMWL ( Table 4). This was also found for a set of snow-dominated catchments in Switzerland (Dietermann and Weiler, 2013) and indicates a similar geographical origin of precipitation during the winter with respect to the other seasons. However, we must mention that the range in the isotopic composition of snow samples was likely underestimated, due to the uncertainty associated with finding sampling locations representative for the isotopic signature of snowpack over the entire catchment.…”

Section: Isotopic Composition Of Snow Snowmelt and Ice Meltmentioning

confidence: 49%

“…However, we must mention that the range in the isotopic composition of snow samples was likely underestimated, due to the uncertainty associated with finding sampling locations representative for the isotopic signature of snowpack over the entire catchment. Indeed, in addition to altitude and seasonal effects, several other factors such as micro-and macro-topography, relocation of snow through wind drift and avalanches, and enrichment of heavy isotopes in upper layers of the snowpack depending on the sun exposure can contribute to significantly enhance the spatial and temporal variability of the isotopic composition of snowpack (Dietermann and Weiler, 2013). Samples collected from melting snow patches showed a wide isotopic range too (Fig.…”

Section: Isotopic Composition Of Snow Snowmelt and Ice Meltmentioning

confidence: 99%

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Tracer-based analysis of spatial and temporal variations of water sources in a glacierized catchment

Penna

Engel

Mao

et al. 2014

Hydrol. Earth Syst. Sci.

116

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Abstract. Snow-dominated and glacierized catchments are important sources of fresh water for biological communities and for populations living in mountain valleys. Gaining a better understanding of the runoff origin and of the hydrological interactions between meltwater, streamflow and groundwater is critical for natural risk assessment and mitigation as well as for effective water resource management in mountain regions. This study is based on the use of stable isotopes of water and electrical conductivity as tracers to identify the water sources for runoff and groundwater and their seasonal variability in a glacierized catchment in the Italian Alps. Samples were collected from rainfall, snow, snowmelt, ice melt, spring and stream water (from the main stream at different locations and from selected tributaries) in 2011, 2012 and 2013. The tracer-based mixing analysis revealed that, overall, snowmelt and glacier melt were the most important endmembers for stream runoff during late spring, summer and early fall. The temporal variability of the tracer concentration suggested that stream water was dominated by snowmelt at the beginning of the melting season (May-June), by a mixture of snowmelt and glacier melt during mid-summer (Julyearly August), and by glacier melt during the end of the summer (end of August-September). The same seasonal pattern observed in streamflow was also evident for groundwater, with the highest electrical conductivity and least negative isotopic values found during cold or relatively less warm periods, when the melt of snowpack and ice was limited. Particularly, the application of a two-component mixing model to data from different springs showed that the snowmelt contribution to groundwater recharge varied between 21 % (±3 %) and 93 % (±1 %) over the season, and the overall contribution during the three study years ranged between 58 % (±24 %) and 72 % (±19 %). These results provided new insights into the isotopic characterization of the study catchment presenting further understanding of the spatio-temporal variability of the main water sources contributing to runoff.

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Section: Isotopic Composition Of Snow Snowmelt and Ice Meltmentioning

confidence: 49%

Section: Isotopic Composition Of Snow Snowmelt and Ice Meltmentioning

confidence: 99%

Tracer-based analysis of spatial and temporal variations of water sources in a glacierized catchment

Penna

Engel

Mao

et al. 2014

Hydrol. Earth Syst. Sci.

116

View full text Add to dashboard Cite

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“…Here, the average isotope composition of precipitation shifts by 1.9‰/100/m for δ 2 H and 0.27‰100/m for δ 18 O, noting that in winter, above around 800 m asl, the precipitation is dominated by snow (Marty, 2008). Some version of this isotopic lapse rate is seen in almost all mountainous environments except on the leeward or "rain-shadow" side of mountains, which receive precipitation from clouds that have already passed over the highest elevation of the ridge and are no longer continuing to rise, keeping the cloud condensation temperature relatively stable (Bershaw, Penny, & Garzione, 2012;Dietermann & Weiler, 2013;Koeniger, Hubbart, Link, & Marshall, 2008;Moran, Marshall, Evans, & Sinclair, 2007;Wen, Tian, Weng, Liu, & Zhao, 2012;Winograd et al, 1998). Moran et al (2007) reported positive isotopic lapse rates (enrichment in heavier isotopes with increasing elevation) in snow samples on the leeward side of a glacierized valley in the Canadian Rockies (refer to Figure 4 in Moran et al (2007)), which may occur only if the warmer temperatures and hence smaller vapor-liquid or vapor-ice isotopic fractionation factors offset the "rain-out" effect.…”

Section: Elevation Gradients and Isotopic Composition Of Precipitationmentioning

confidence: 99%

“…It has been widely observed that early meltwater is more depleted in heavier isotopes and that, as the melt season progresses, both the residual snowpack and the generated meltwater become more enriched in heavier isotopes (Dietermann & Weiler, 2013;Taylor et al, 2001), which is also referred to as the melt-out effect (Ala-aho et al, 2017). To the best of our knowledge, the physical mechanisms of this melt-out effect are not well understood but likely involve the partial melting of snowpack which results in preferential loss of lighter isotopes in the early season meltwater.…”

Section: Snow Metamorphism and Snowmeltmentioning

confidence: 99%

Understanding snow hydrological processes through the lens of stable water isotopes

Beria¹,

Larsen²,

Ceperley³

et al. 2017

Preprint

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Snowfall may have different stable isotopic compositions compared with rainfall, allowing its contribution to potentially be tracked through the hydrological cycle. This review summarizes the state of knowledge of how different hydrometeorological processes affect the isotopic composition of snow in its different forms (snowfall, snowpack, and snowmelt), and, through selected examples, discusses how stable water isotopes can provide a better understanding of snow hydrological processes. A detailed account is given of how the variability in isotopic composition of snow changes from precipitation to final melting. The effect of different snow ablation processes (sublimation, melting, and redistribution by wind or avalanches) on the isotope ratios of the underlying snowpack are also examined. Insights into the role of canopy in snow interception processes, and how the isotopic composition in canopy underlying snowpacks can elucidate the exchanges therein are discussed, as well as case studies demonstrating the usefulness of stable water isotopes to estimate seasonality in the groundwater recharge. Rain-on-snow floods illustrate how isotopes can be useful to estimate the role of preferential flow during heavy spring rains. All these examples point to the complexity of snow hydrologic processes and demonstrate that an isotopic approach is useful to quantify snow contributions throughout the water cycle, especially in high-elevation and highlatitude catchments, where such processes are most pronounced. This synthesis concludes by tracing a snow particle along its entire hydrologic life cycle, highlights the major practical challenges remaining in snow hydrology and discusses future research directions.

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“…The effect of the aspect of the hillslopes on isotopic variability and IHS results in topographically complex terrain has been rarely investigated. Dahlke and Lyon (2013) and Dietermann and Weiler (2013) surveyed the snowpack isotopic composition and showed a notable spatial variability in their data, particularly between north-and south-facing slopes. They conclude that the spatial variability of snowmelt could be high and that the timing of meltwater varies with the morphology of the catchment.…”

Section: Introductionmentioning

confidence: 99%

The importance of snowmelt spatiotemporal variability for isotope-based hydrograph separation in a high-elevation catchment

Schmieder

Hanzer

Marke

et al. 2016

Hydrol. Earth Syst. Sci.

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Abstract. Seasonal snow cover is an important temporary water storage in high-elevation regions. Especially in remote areas, the available data are often insufficient to accurately quantify snowmelt contributions to streamflow. The limited knowledge about the spatiotemporal variability of the snowmelt isotopic composition, as well as pronounced spatial variation in snowmelt rates, leads to high uncertainties in applying the isotope-based hydrograph separation method. The stable isotopic signatures of snowmelt water samples collected during two spring 2014 snowmelt events at a north-and a south-facing slope were volume weighted with snowmelt rates derived from a distributed physicsbased snow model in order to transfer the measured plotscale isotopic composition of snowmelt to the catchment scale. The observed δ 18 O values and modeled snowmelt rates showed distinct inter-and intra-event variations, as well as marked differences between north-and south-facing slopes. Accounting for these differences, two-component isotopic hydrograph separation revealed snowmelt contributions to streamflow of 35 ± 3 and 75 ± 14 % for the early and peak melt season, respectively. These values differed from those determined by formerly used weighting methods (e.g., using observed plot-scale melt rates) or considering either the north-or south-facing slope by up to 5 and 15 %, respectively.

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Spatial distribution of stable water isotopes in alpine snow cover

Cited by 47 publications

References 31 publications

Tracer-based analysis of spatial and temporal variations of water sources in a glacierized catchment

Tracer-based analysis of spatial and temporal variations of water sources in a glacierized catchment

Understanding snow hydrological processes through the lens of stable water isotopes

The importance of snowmelt spatiotemporal variability for isotope-based hydrograph separation in a high-elevation catchment

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