Your search keyword '"Garvelmann, Jakob"' showing total 10 results

1. Risk of groundwater contamination widely underestimated because of fast flow into aquifers

Author

Hartmann, Andreas, Jasechko, Scott, Gleeson, Tom, Wada, Yoshihide, Andreo, Bartolomé, Barberá, Juan Antonio, Brielmann, Heike, Bouchaou, Lhoussaine, Charlier, Jean-Baptiste, Darling, W. George, Filippini, Maria, Garvelmann, Jakob, Goldscheider, Nico, Kralik, Martin, Kunstmann, Harald, Ladouche, Bernard, Lange, Jens, Lucianetti, Giorgia, Martín, José Francisco, Mudarra, Matías, Sánchez, Damián, Stumpp, Christine, Zagana, Eleni, and Wagener, Thorsten

Published

2021

2. Quantification and characterization of the dynamics of spring and stream water systems in the Berchtesgaden Alps with a long-term stable isotope dataset

Author

Garvelmann, Jakob, Warscher, Michael, Leonhardt, Gabriele, Franz, Helmut, Lotz, Annette, and Kunstmann, Harald

Published

2017

3. Modelling forest snow processes with a new version of WaSiM.

Author

Förster, Kristian, Garvelmann, Jakob, Meißl, Gertraud, and Strasser, Ulrich

Subjects

*FORESTS & forestry, *SNOW, *WATER balance (Hydrology), *METEOROLOGICAL services, *WATERSHEDS, *PLANT canopies

Abstract

We present a new model extension for the Water balance Simulation Model, WaSiM, which features (i) snow interception and (ii) modified meteorological conditions under coniferous forest canopies, complementing recently developed model extensions for particular mountain hydrological processes. Two study areas in Austria and Germany are considered in this study. To supplement and constrain the modelling experiments with on-site observations, a network of terrestrial time-lapse cameras was set up in one of these catchments. The spatiotemporal patterns of snow depth inside the forest and at the adjacent open field sites were recorded along with snow interception dynamics. Comparison of observed and modelled snow cover and canopy interception indicates that the new version of WaSiM reliably reconstructs the variability of snow accumulation for both the forest and the open field. The Nash-Sutcliffe efficiency computed for selected runoff events in spring increases from −0.68 to 0.71 and 0.21 to 0.87, respectively. [ABSTRACT FROM AUTHOR]

Published

2018

4. Spatio‐temporal tracer variability in the glacier melt end‐member — How does it affect hydrograph separation results?

Author

Schmieder, Jan, Marke, Thomas, Strasser, Ulrich, and Garvelmann, Jakob

Subjects

GLACIAL melting, GROUNDWATER tracers, HYDROGRAPHY, MOUNTAIN hydrology, STREAMFLOW

Abstract

Abstract: Geochemical and isotopic tracers were often used in mixing models to estimate glacier melt contributions to streamflow, whereas the spatio‐temporal variability in the glacier melt tracer signature and its influence on tracer‐based hydrograph separation results received less attention. We present novel tracer data from a high‐elevation catchment (17 km2, glacierized area: 34%) in the Oetztal Alps (Austria) and investigated the spatial, as well as the subdaily to monthly tracer variability of supraglacial meltwater and the temporal tracer variability of winter baseflow to infer groundwater dynamics. The streamflow tracer variability during winter baseflow conditions was small, and the glacier melt tracer variation was higher, especially at the end of the ablation period. We applied a three‐component mixing model with electrical conductivity and oxygen‐18. Hydrograph separation (groundwater, glacier melt, and rain) was performed for 6 single glacier melt‐induced days (i.e., 6 events) during the ablation period 2016 (July to September). Median fractions (±uncertainty) of groundwater, glacier melt, and rain for the events were estimated at 49±2%, 35±11%, and 16±11%, respectively. Minimum and maximum glacier melt fractions at the subdaily scale ranged between 2±5% and 76±11%, respectively. A sensitivity analysis showed that the intraseasonal glacier melt tracer variability had a marked effect on the estimated glacier melt contribution during events with large glacier melt fractions of streamflow. Intra‐daily and spatial variation of the glacier melt tracer signature played a negligible role in applying the mixing model. The results of this study (a) show the necessity to apply a multiple sampling approach in order to characterize the glacier melt end‐member and (b) reveal the importance of groundwater and rainfall–runoff dynamics in catchments with a glacial flow regime. [ABSTRACT FROM AUTHOR]

Published

2018

5. Quantification and characterization of the dynamics of spring and stream water systems in the Berchtesgaden Alps with a long-term stable isotope dataset.

Author

Warscher, Michael, Kunstmann, Harald, Garvelmann, Jakob, Leonhardt, Gabriele, Franz, Helmut, and Lotz, Annette

Subjects

STREAM chemistry, ISOTOPIC analysis, HYDROLOGY, WATER springs, PRECIPITATION (Chemistry)

Abstract

The understanding of alpine groundwater dynamics and the interactions with surface stream water is crucial for water resources research and management in mountain regions. In order to characterize local spring and stream water systems, samples at 8 springs, 5 stream gauges and bulk samples of precipitation at 4 sites were regularly collected between January 2012 and January 2016 in the Berchtesgaden Alps for stable water isotope analysis. The sampled hydro-systems are characterized by very different dynamics of the stable isotope signatures. To quantify those differences, we analyzed the stable isotope time series and calculated mean transit times (MTT) and young water fractions (YWF) of the sampled systems. Based on the data analysis, two groups of spring systems could be identified: one group with relatively short MTT (and high YWF) and another group with long MTT (and low YWF). The MTT and the YWF of the sampled streams were intermediate, respectively. The reaction of the sampled spring and stream systems to precipitation input was studied by lag time analysis. The average lag times revealed the influence of snow and ice melt for the hydrology in the study region. It was not possible to determine the recharge elevation of the spring and stream systems due to a lack of altitude effect in the precipitation data. For two catchments, the influence of the spring water stable isotopic composition on the streamflow was shown, highlighting the importance of the spring water for the river network in the study area. [ABSTRACT FROM AUTHOR]

Published

2017

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

Author

Schmieder, Jan, Hanzer, Florian, Marke, Thomas, Garvelmann, Jakob, Warscher, Michael, Kunstmann, Harald, Strasser, Ulrich, and Pohl, S.

Subjects

SNOWMELT, SPATIOTEMPORAL processes, HYDROGRAPHY, WATERSHEDS, SNOW cover, WATER storage

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 δ18O 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. [ABSTRACT FROM AUTHOR]

Published

2016

7. The importance of spatio-temporal snowmelt variability for isotopic hydrograph separation in a high-elevation catchment.

Author

Schmieder, Jan, Hanzer, Florian, Marke, Thomas, Garvelmann, Jakob, Warscher, Michael, Kunstmann, Harald, and Strasser, Ulrich

Abstract

Seasonal snow cover is an important temporary water storage in high-elevation regions. Especially in remote areas, the available data is often insufficient to explicitly quantify snowmelt contributions to streamflow. The unknown spatio-temporal variability of the snowmelt isotopic content, as well as pronounced spatial variations of snowmelt rates lead to high uncertainties in applying the isotopic hydrograph separation method. This study presents an approach that uses a distributed snowmelt model to support the traditional isotopic hydrograph separation technique. 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 physics-based snow model in order to transfer the measured plot-scale isotopic content of snowmelt water to the catchment scale. The observed ƍ18O values and modelled snowmelt rates showed distinct inter- and intra-event variations, as well as marked differences between north- and south-facing slopes. Accounting for those differences, two-component isotopic hydrograph separation revealed snowmelt contributions of 35 ± 3% and 75 ± 14% for the early and peak melt season, respectively. Differences to formerly used weighting methods (e.g. using observed plot-scale melt rates) or considering either the north- or south-facing slope were up to 5 and 15%, respectively. [ABSTRACT FROM AUTHOR]

Published

2016

8. Spatio-temporal controls of snowmelt and runoff generation during rain-on-snow events in a mid-latitude mountain catchment.

Author

Garvelmann, Jakob, Pohl, Stefan, and Weiler, Markus

Subjects

SPATIO-temporal variation, SNOWMELT, RUNOFF, WATERSHEDS, HYDROLOGICAL research, FLOODS

Abstract

A network of 30 standalone snow monitoring stations was used to investigate the snow cover distribution, snowmelt dynamics, and runoff generation during two rain-on-snow (ROS) events in a 40 km2 montane catchment in the Black Forest region of southwestern Germany. A multiple linear regression analysis using elevation, aspect, and land cover as predictors for the snow water equivalent (SWE) distribution within the catchment was applied on an hourly basis for two significant ROS flood events that occurred in December 2012. The available snowmelt water, liquid precipitation, as well as the total retention storage of the snow cover were considered in order to estimate the amount of water potentially available for the runoff generation. The study provides a spatially and temporally distributed picture of how the two observed ROS floods developed in the catchment. It became evident that the retention capacity of the snow cover is a crucial mechanism during ROS. It took several hours before water was released from the snowpack during the first ROS event, while retention storage was exceeded within 1 h from the start of the second event. Elevation was the most important terrain feature. South-facing terrain contributed more water for runoff than north-facing slopes, and only slightly more runoff was generated at open compared to forested areas. The results highlight the importance of snowmelt together with liquid precipitation for the generation of flood runoff during ROS and the large temporal and spatial variability of the relevant processes. Copyright © 2015 John Wiley & Sons, Ltd. [ABSTRACT FROM AUTHOR]

Published

2015

9. Potential of a low-cost sensor network to understand the spatial and temporal dynamics of a mountain snow cover.

Author

Pohl, Stefan, Garvelmann, Jakob, Wawerla, Jens, and Weiler, Markus

Subjects

SNOW cover, HYDROLOGY, CLIMATOLOGY, VEGETATION & climate, FOREST plants

Abstract

The spatial and temporal dynamics of seasonal snow covers play a critical role for many hydrological, ecological, and climatic processes. This paper presents a new, innovative approach to continuously monitor these dynamics using numerous low-cost, standalone snow monitoring stations (SnoMoS). These stations provide snow and related meteorological data with a high temporal and spatial resolution. Data collected by SnoMoS include: snow depth, surface temperature, air temperature and humidity, total precipitation, global radiation, wind speed, and barometric pressure. A total of 99 sensors were placed over the winters 2010/2011 and 2011/2012 at multiple locations within three 40-180 km2 basins in the Black Forest region of Southern Germany. The locations were chosen to cover a wide range of slopes, elevations, and expositions in a stratified sampling design. Furthermore, 'paired stations' located in close proximity to each other, one in the open and one underneath various forest canopies, were set up to investigate the influence of vegetation on snow dynamics. The results showed that considerable differences in snow depth and, therefore, snow water equivalent (SWE) are present within the study area despite its moderate temperatures and medium elevation range (400-1500 m). The relative impact of topographical factors like elevation, aspect, and of different types of forest vegetation were quantified continuously and were found to change considerably over the winter period. The recorded differences in SWE and snow cover duration were large enough that they should be considered in hydrologic and climate models. [ABSTRACT FROM AUTHOR]

Published

2014

10. Revisiting Forest Effects on Winter Air Temperature and Wind Speed—New Open Data and Transfer Functions.

Author

Klein, Michael, Garvelmann, Jakob, and Förster, Kristian

Subjects

*ATMOSPHERIC temperature, *WIND speed, *TRANSFER functions, *WIND speed measurement, *LEAF area index

Abstract

The diurnal cycle of both air temperature and wind speed is characterized by considerable differences, when comparing open site conditions to forests. In the course of this article, a new two-hourly, open-source dataset, covering a high spatial and temporal variability, is presented and analyzed. It contains air temperature measurements (128 station pairs (open/forest); six winter seasons; six study sites), wind speed measurements (64 station pairs; three winter seasons, four study sites) and related metadata in central Europe. Daily cycles of air temperature and wind speed, as well as further dependencies of the effective Leaf Area Index (effective LAI), the exposure in the context of forest effects, and the distance to the forest edge, are illustrated in this paper. The forest effects on air temperature can be seen particularly with increasing canopy density, in southern exposures, and in the late winter season, while wind speed depends on multiple factors such as effective LAI or the distance to the forest edge. New transfer functions, developed using linear and non-linear regression analysis, in a leave-one-out cross-validation, improve certain efficiency criteria (NSME; r2; RMSE; MAE) compared to existing transfer functions. The dataset enables multiple purposes and capabilities due to its diversity and sample size. [ABSTRACT FROM AUTHOR]

Published

2021