Your search keyword '"alpine watersheds"' showing total 13 results

1. Method for assigning hydrological computational units in alpine watersheds

Author

Yuheng Yang, Baisha Weng, Denghua Yan, Yongzhen Niu, Xiaoyan Gong, and Meng Li

Subjects

Hydrological computational units, Montane altitudinal zones, Climate change, Alpine watersheds, Qinghai–Tibet Plateau, Physical geography, GB3-5030, Geology, QE1-996.5

Abstract

Study region: The Nagqu River Watershed in the Qinghai–Tibet Plateau. Study focus: A computational unit is the basic spatial unit employed in distributed hydrological models (DHMs), which combines the spatiotemporal distributions of meteorological variables and physical parameters denoted within a region to reveal the characteristics affecting the water cycle of watersheds. However, the current methods developed for spatially divided regions into computational units fail to consider the physical meaning and impact of climate change in montane altitudinal zones (MAZs), which significantly affects alpine watersheds. This study proposes a method for assigning the computational units of alpine DHMs according to one-period MAZ that explicitly account for physical meaning and climate change. New hydrological insights for the region: The benefits of the proposed altitudinal discretization method are verified by applying it to construct a DHM based on the water and energy transfer processes in large river basins (WEP-L) models. The results obtained using the WEP-L, SWAT model and the new regional division method (denoted as the WEP-C model) that applies the proposed altitudinal discretization method are compared. The results demonstrate that the simulation accuracy of the daily and monthly streamflows and daily soil moisture from the alpine watershed is improved by the use of the proposed altitudinal discretization method, which provide guidance for further DHM development and can be applied to other hydrological models.

Published

2020

2. Temporal and spatial variability of cation and silica export in an alpine watershed, Emerald Lake, California

Author

Meixner, T, Shaw, JR, and Bales, RC

Subjects

snow hydrology, mineral weathering, acid deposition, granite, alpine watersheds, Physical Geography and Environmental Geoscience, Civil Engineering, Environmental Engineering

Published

2004

3. Relevance and Scale Dependence of Hydrological Changes in Glacierized Catchments: Insights from Historical Data Series in the Eastern Italian Alps

Author

Luca Carturan, Fabrizio De Blasi, Federico Cazorzi, Davide Zoccatelli, Paola Bonato, Marco Borga, and Giancarlo Dalla Fontana

Subjects

glacier runoff change, climate change, alpine watersheds, Italian Alps, glacio-hydrological modeling, historical data series, Hydraulic engineering, TC1-978, Water supply for domestic and industrial purposes, TD201-500

Abstract

Glaciers have an important hydrological buffering effect, but their current rapid reduction raises concerns about future water availability and management. This work presents a hydrological sensitivity analysis to different climatic and glacier cover conditions, carried out over four catchments with area between 8 and 1050 km2, and with glacierization between 2% and 70%, in the Italian Alps. The analysis is based on past observations, and exploits a unique dataset of glacier change and hydro-meteorological data. The working approach is aimed at avoiding uncertainties typical of future runoff projections in glacierized catchments. The results highlight a transition from glacial to nival hydrological regime, with the highest impacts in August runoff over smaller catchments. The buffering effect of current glaciers has largely decreased if compared to the Little Ice Age, up to 75% for larger catchments, but it is still important during warm and dry summers like 2003. We confirm a non-linear relationship between glacier contribution in late summer and catchment area/percent glacierization. The peak in runoff attributable to glacier melt, expected in the next 2–3 decades on highly glacierized alpine catchments, has already passed in the study area.

Published

2019

4. Assessment of suspended sediment transport in four alpine watersheds (France): influence of the climatic regime.

Author

Mano, Vincent, Nemery, Julien, Belleudy, Philippe, and Poirel, Alain

Subjects

SEDIMENT transport, SUSPENDED sediments, CLIMATE change, STORMS, METEOROLOGICAL precipitation, WATERSHEDS, NATURE reserves, HYDROLOGY

Abstract

The article presents the result of the study that examines the influence of the climatic regime to the suspended sediment transport in four alpine watersheds in France, namely: the Asse, Bléone, Romanche and Ferrand. The study shows that the suspended sediment transport on the Asse and Bléone rivers were caused by violent storms. In Ferrand and Romanche, the sediment transport was also caused by local storms and snowmelt or icemelt which occurred from April to October. Moreover, water discharge and precipitations were the main processes involved in suspended sediment production.

Published

2009

5. Method for assigning hydrological computational units in alpine watersheds

Author

Niu Yongzhen, Gong Xiaoyan, Denghua Yan, Li Meng, Yuheng Yang, and Baisha Weng

Subjects

Watershed, 010504 meteorology & atmospheric sciences, Discretization, 0207 environmental engineering, Drainage basin, Climate change, 02 engineering and technology, 01 natural sciences, Qinghai–Tibet Plateau, Earth and Planetary Sciences (miscellaneous), SWAT model, Water cycle, 020701 environmental engineering, lcsh:Physical geography, 0105 earth and related environmental sciences, Water Science and Technology, Hydrology, geography, Montane altitudinal zones, Plateau, geography.geographical_feature_category, Alpine watersheds, lcsh:QE1-996.5, Hydrological computational units, lcsh:Geology, Current (stream), Environmental science, lcsh:GB3-5030

Abstract

Study region The Nagqu River Watershed in the Qinghai–Tibet Plateau. Study focus A computational unit is the basic spatial unit employed in distributed hydrological models (DHMs), which combines the spatiotemporal distributions of meteorological variables and physical parameters denoted within a region to reveal the characteristics affecting the water cycle of watersheds. However, the current methods developed for spatially divided regions into computational units fail to consider the physical meaning and impact of climate change in montane altitudinal zones (MAZs), which significantly affects alpine watersheds. This study proposes a method for assigning the computational units of alpine DHMs according to one-period MAZ that explicitly account for physical meaning and climate change. New hydrological insights for the region The benefits of the proposed altitudinal discretization method are verified by applying it to construct a DHM based on the water and energy transfer processes in large river basins (WEP-L) models. The results obtained using the WEP-L, SWAT model and the new regional division method (denoted as the WEP-C model) that applies the proposed altitudinal discretization method are compared. The results demonstrate that the simulation accuracy of the daily and monthly streamflows and daily soil moisture from the alpine watershed is improved by the use of the proposed altitudinal discretization method, which provide guidance for further DHM development and can be applied to other hydrological models.

Published

2020

6. Assessment of episodic acidification in Sierra Nevada, California.

Author

Nikolaidis, Nikolaos, Nikolaidis, Vicki, and Schnoor, Jerald

Abstract

Monte-Carlo simulations were used to assess the extent of shortterm alkalinity depressions occuring in Sierra Nevada lakes due to acidic deposition events. The Episodic Event Model (EEM) was used to simulate spring snowmelt events. Snow course data, precipitation data and lake acidification surveys were used to derive values for the EEM parameters. Spring snowmelt events were shown to have great impacts on the water quality of Sierran lakes. Lakes are likely to be most affected by the early-spring snowmelt event because the epilimnion depth is at a minimum, which indicates minimum dilution. Under annual average loading conditions, no Sierran lake has been reported as acidic although 29% of the lakes have alkalinities less than 40 µeq/L indicating a sensitivity to acidification. In simulations of early-spring snowmelt events, using present-day acidic loading conditions, it was estimated 79% ± 9% of the lakes would experience shortterm lake alkalinity depressions to levels less than 40 µeq/L. The results provided by the model simulations are valuable in establishing upper and lower limits on the extent of possible episodic acidification to lake-resources-at-risk. The most critical parameters controlling the magnitude of lake alkalinity depressions during snowmelt episodic events are a) the lake area to watershed area ratio - a measure of input loading, and b) the epilimnion volume - a measure of dilution and mixing. [ABSTRACT FROM AUTHOR]

Published

1991

7. Relevance and Scale Dependence of Hydrological Changes in Glacierized Catchments: Insights from Historical Data Series in the Eastern Italian Alps

Author

Paola Bonato, Giancarlo Dalla Fontana, Luca Carturan, Fabrizio de Blasi, Federico Cazorzi, Marco Borga, and Davide Zoccatelli

Subjects

lcsh:Hydraulic engineering, 010504 meteorology & atmospheric sciences, alpine watersheds, Geography, Planning and Development, 0207 environmental engineering, Climate change, 02 engineering and technology, Data series, Aquatic Science, 01 natural sciences, Biochemistry, historical data series, Alpine watersheds, Glacier runoff change, Glacio-hydrological modeling, Historical data series, Italian Alps, Water Science and Technology, lcsh:Water supply for domestic and industrial purposes, lcsh:TC1-978, Glacial period, 020701 environmental engineering, 0105 earth and related environmental sciences, Planning and Development, lcsh:TD201-500, geography, geography.geographical_feature_category, Geography, Glacier, glacier runoff change, Current (stream), climate change, glacio-hydrological modeling, Environmental science, Catchment area, Physical geography, Scale (map), Surface runoff

Abstract

Glaciers have an important hydrological buffering effect, but their current rapid reduction raises concerns about future water availability and management. This work presents a hydrological sensitivity analysis to different climatic and glacier cover conditions, carried out over four catchments with area between 8 and 1050 km2, and with glacierization between 2% and 70%, in the Italian Alps. The analysis is based on past observations, and exploits a unique dataset of glacier change and hydro-meteorological data. The working approach is aimed at avoiding uncertainties typical of future runoff projections in glacierized catchments. The results highlight a transition from glacial to nival hydrological regime, with the highest impacts in August runoff over smaller catchments. The buffering effect of current glaciers has largely decreased if compared to the Little Ice Age, up to 75% for larger catchments, but it is still important during warm and dry summers like 2003. We confirm a non-linear relationship between glacier contribution in late summer and catchment area/percent glacierization. The peak in runoff attributable to glacier melt, expected in the next 2&ndash, 3 decades on highly glacierized alpine catchments, has already passed in the study area.

Published

2019

8. Assessment of suspended sediment transport in four alpine watersheds (France): influence of the climatic regime

Author

Alain Poirel, Julien Némery, Philippe Belleudy, Vincent Mano, Laboratoire d'étude des transferts en hydrologie et environnement (LTHE), Centre National de la Recherche Scientifique (CNRS)-Institut National Polytechnique de Grenoble (INPG)-Institut national des sciences de l'Univers (INSU - CNRS)-Université Joseph Fourier - Grenoble 1 (UJF)-Observatoire des Sciences de l'Univers de Grenoble (OSUG), Université Savoie Mont Blanc (USMB [Université de Savoie] [Université de Chambéry])-Institut polytechnique de Grenoble - Grenoble Institute of Technology (Grenoble INP)-Institut national de recherche en sciences et technologies pour l'environnement et l'agriculture (IRSTEA)-Université Joseph Fourier - Grenoble 1 (UJF)-Institut national des sciences de l'Univers (INSU - CNRS)-Centre National de la Recherche Scientifique (CNRS)-Université Grenoble Alpes (UGA)-Université Savoie Mont Blanc (USMB [Université de Savoie] [Université de Chambéry])-Institut polytechnique de Grenoble - Grenoble Institute of Technology (Grenoble INP)-Institut national de recherche en sciences et technologies pour l'environnement et l'agriculture (IRSTEA)-Centre National de la Recherche Scientifique (CNRS)-Université Grenoble Alpes (UGA), Institut National Polytechnique de Grenoble (INPG)-Centre National de la Recherche Scientifique (CNRS)-Observatoire des Sciences de l'Univers de Grenoble (OSUG), and Université Joseph Fourier - Grenoble 1 (UJF)-Institut polytechnique de Grenoble - Grenoble Institute of Technology (Grenoble INP )-Institut national des sciences de l'Univers (INSU - CNRS)-Institut national de recherche en sciences et technologies pour l'environnement et l'agriculture (IRSTEA)-Université Savoie Mont Blanc (USMB [Université de Savoie] [Université de Chambéry])-Centre National de la Recherche Scientifique (CNRS)-Université Joseph Fourier - Grenoble 1 (UJF)-Institut polytechnique de Grenoble - Grenoble Institute of Technology (Grenoble INP )-Institut national des sciences de l'Univers (INSU - CNRS)-Institut national de recherche en sciences et technologies pour l'environnement et l'agriculture (IRSTEA)-Université Savoie Mont Blanc (USMB [Université de Savoie] [Université de Chambéry])-Centre National de la Recherche Scientifique (CNRS)

Subjects

snowmelt, 010504 meteorology & atmospheric sciences, [SDE.MCG]Environmental Sciences/Global Changes, 0207 environmental engineering, 02 engineering and technology, Rating curve, 01 natural sciences, suspended sediment transport, [SDU.STU.HY]Sciences of the Universe [physics]/Earth Sciences/Hydrology, Turbidity, 020701 environmental engineering, 0105 earth and related environmental sciences, Water Science and Technology, Hydrology, Suspended solids, Alpine watersheds, Sediment, high-frequency sampling, turbidity, 6. Clean water, Turbidite, Mediterranean watersheds, [SDU.STU.CL]Sciences of the Universe [physics]/Earth Sciences/Climatology, 13. Climate action, Snowmelt, Environmental science, Surface runoff, Sediment transport

Abstract

High-frequency water discharge and suspended sediment concentration (SSC) databases were collected for 3 years on four contrasted watersheds: the Asse and the Bleone (two Mediterranean rainfall regime watersheds) and the Romanche and the Ferrand (two rainfall–snowmelt regime watersheds). SSCs were calculated from turbidity recordings (1-h time step), converted into SSC values. The rating curve was calculated by means of simultaneous SSC measurement taken by water sampling and turbidity recording. Violent storms during springtime and autumn were responsible for suspended sediment transport on the Asse and the Bleone rivers. On the Ferrand and the Romanche, a large share of suspended sediment transport was also caused by local storms, but 30% of annual fluxes results from snowmelt or icemelt which occurred from April to October. On each watershed, SSC up to 50 g l−1 were observed. Annual specific fluxes ranged from 450 to 800 t km−2 year−1 and 40–80% of annual suspended sediment fluxes occurred within 2% of the time. These general indicators clearly demonstrate the intensity of suspended sediment transport on these types of watersheds. Suspended sediment fluxes proved to be highly variable at the annual scale (inter-annual variability of specific fluxes) as well as at the event scale (through a hysteresis loop in the SSC/Q relationship) on these watersheds. In both cases, water discharge and precipitations were the main processes involved in suspended sediment production and transport. The temporal and spatial variability of hydro-meteorological processes on the watershed provides a better understanding of suspended sediment dynamics. Copyright © 2009 John Wiley & Sons, Ltd.

Published

2009

9. Relevance and Scale Dependence of Hydrological Changes in Glacierized Catchments: Insights from Historical Data Series in the Eastern Italian Alps.

Author

Carturan, Luca, De Blasi, Fabrizio, Cazorzi, Federico, Zoccatelli, Davide, Bonato, Paola, Borga, Marco, and Dalla Fontana, Giancarlo

Subjects

GLACIERS, HYDROLOGY, SNOWMELT, RUNOFF, WATERSHEDS

Abstract

Glaciers have an important hydrological buffering effect, but their current rapid reduction raises concerns about future water availability and management. This work presents a hydrological sensitivity analysis to different climatic and glacier cover conditions, carried out over four catchments with area between 8 and 1050 km2, and with glacierization between 2% and 70%, in the Italian Alps. The analysis is based on past observations, and exploits a unique dataset of glacier change and hydro-meteorological data. The working approach is aimed at avoiding uncertainties typical of future runoff projections in glacierized catchments. The results highlight a transition from glacial to nival hydrological regime, with the highest impacts in August runoff over smaller catchments. The buffering effect of current glaciers has largely decreased if compared to the Little Ice Age, up to 75% for larger catchments, but it is still important during warm and dry summers like 2003. We confirm a non-linear relationship between glacier contribution in late summer and catchment area/percent glacierization. The peak in runoff attributable to glacier melt, expected in the next 2–3 decades on highly glacierized alpine catchments, has already passed in the study area. [ABSTRACT FROM AUTHOR]

Published

2019

10. Climate change will affect hydrological regimes in the Alps

Author

Confortola, Gabriele, Soncini, Andrea, and Bocchiola, Daniele

Subjects

Physical geography, climate change, GCM models, Alpine watersheds, Geography. Anthropology. Recreation, hydrological projections, GB3-5030

Abstract

Climate change will affect hydrological cycle and water resources in the Alps. Here we sketched potential future (2045-2054) hydrological cycle under prospective climate change scenarios within an Alpine river of Italy: Serio (ca. 300 km2). Therein, hydrology is highly dependent upon snow cover cycle, very likely to be affected by climate changes. We set up and validated a hydrological model able to mimic water resources regime of the river. We then use downscaled future temperature and precipitation from two general circulation models GCMs to feed the hydrological model and obtain projected hydrological regimes, at flow sections at different altitudes within the catchment. The scenarios and storylines from the adopted GCMs differ from one another with respect to projected precipitation and temperature amount, but agree upon decrease of the former and increase of the latter. All hydrological scenarios agree upon prospective shrinkage of seasonal snow cover due to increased temperature, and upon prospective increase of Fall and Winter stream flows as due to increased liquid precipitation. Lower discharges are projected during Spring and Summer, in view of decreased rainfall and snow cover at thaw, and the CCSM3 model provides shifting of thaw season to one month earlier. Higher catchments are more impacted because Winter flows increase more proportionally.

Published

2014

11. Gli effetti del cambiamento climatico sul regime idrologico nelle Alpi: Un caso di studio in Italia = Climate change will affect hydrological regimes in the Alps: A case study in Italy

Author

Confortola, Gabriele, Soncini, Andrea, and Bocchiola, Daniele

Subjects

Planning and Development, GCM models, Alpine watersheds, Geography, Climate change, Hydrological projections, Geography, Planning and Development, Earth-Surface Processes

Published

2013

12. Temporal and spatial variability of cation and silica export in an alpine watershed, Emerald Lake, California

Author

Roger C. Bales, Thomas Meixner, and J. R. Shaw

Subjects

Hydrology, geography, Watershed, geography.geographical_feature_category, Environmental Engineering, Lithology, Bedrock, alpine watersheds, Drainage basin, Weathering, Civil Engineering, Physical Geography and Environmental Geoscience, Snowmelt, mineral weathering, snow hydrology, acid deposition, Spatial variability, Surface runoff, Geology, Water Science and Technology, granite

Abstract

A reaction set of possible mineral weathering reactions is proposed to explain observed cation and silica export for the Emerald Lake watershed, a small Sierra Nevada, California catchment. The reaction set was calculated through a stoichiometric mole-balance method, using a multiyear record of stream flow and snowpack chemical analyses and site-specific mineral compositions. Reaction-set calculations were intended to explore how the processes controlling stream cation and silica export depend on differing bedrock mineralogy across the catchment as snowmelt and runoff patterns change over the year. Different regions within the watershed can be differentiated by lake inflow subdrainages, each exhibiting different stream-flow chemistry and calculated weathering stoichiometry, indicating that different silica and cation generation processes are dominant in wet steep portions of the catchment. Short-term differences in stream concentrations were assumed to reflect ion exchange equilibria and rapid biological processes, whereas long-term persistent stream concentration differences in different areas of the catchment were assumed to reflect spatial variability in mineral weathering stoichiometry. Mineralogical analyses of rock samples from the watershed provided site-specific chemical compositions of major mineral species for reaction calculations. Reaction sets were evaluated by linear regression of calculated versus observed differences between snowmelt and stream-flow chemistry and by a combined measure. Initially, single weathering reactions were balanced and evaluated to determine the reactions that best explained observed stream chemical export. Next, reactions were combined, using mineral compositions from different rock types to estimate the dependence of ion fluxes on lithology. The seasonal variability of major solute calculated fluxes is low, approximately one order of magnitude, relative to the observed three orders of magnitude variability in basin discharge. Reaction sets using basin-averaged lithology and Aplite lithologies gave superior explanations of stream chemical composition. Copyright © 2004 John Wiley & Sons, Ltd.

Published

2004

13. Climate change will affect hydrological regimes in the Alps

Author

Gabriele Confortola, Andrea Soncini, and Daniele Bocchiola

Subjects

climate change, Alpine watersheds, GCM models, hydrological projections, Geography. Anthropology. Recreation, Physical geography, GB3-5030

Abstract

Climate change will affect hydrological cycle and water resources in the Alps. Here we sketched potential future (2045-2054) hydrological cycle under prospective climate change scenarios within an Alpine river of Italy: Serio (ca. 300 km2). Therein, hydrology is highly dependent upon snow cover cycle, very likely to be affected by climate changes. We set up and validated a hydrological model able to mimic water resources regime of the river. We then use downscaled future temperature and precipitation from two general circulation models GCMs to feed the hydrological model and obtain projected hydrological regimes, at flow sections at different altitudes within the catchment. The scenarios and storylines from the adopted GCMs differ from one another with respect to projected precipitation and temperature amount, but agree upon decrease of the former and increase of the latter. All hydrological scenarios agree upon prospective shrinkage of seasonal snow cover due to increased temperature, and upon prospective increase of Fall and Winter stream flows as due to increased liquid precipitation. Lower discharges are projected during Spring and Summer, in view of decreased rainfall and snow cover at thaw, and the CCSM3 model provides shifting of thaw season to one month earlier. Higher catchments are more impacted because Winter flows increase more proportionally.