Unterschiede
Hier werden die Unterschiede zwischen zwei Versionen angezeigt.
| thesis:water_balance_roger [2023/12/12 17:48] – angelegt s.gnann | thesis:water_balance_roger [2023/12/12 17:49] (aktuell) – s.gnann | ||
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| ** Background and aim ** | ** Background and aim ** | ||
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| Models are used to test our understanding of hydrological systems, to estimate hydrological variables in places without observations, | Models are used to test our understanding of hydrological systems, to estimate hydrological variables in places without observations, | ||
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| This project investigates the representation of the short and long-term water balance in the hydrological model RoGeR (Runoff Generation Research; Schwemmle et al., 2023), in particular how the model partitions the incoming precipitation into evaporation and streamflow. You will first investigate the spatial variability of the long-term water balance for different catchments in Baden-Württemberg. You will then also investigate the temporal variability within these catchments by examining annual water balances. By performing the same analysis with both modelled and observational data, you will be able to investigate the functioning of the model and how well it represents the real world. For example, if the model produces too much streamflow in comparison to observations, | This project investigates the representation of the short and long-term water balance in the hydrological model RoGeR (Runoff Generation Research; Schwemmle et al., 2023), in particular how the model partitions the incoming precipitation into evaporation and streamflow. You will first investigate the spatial variability of the long-term water balance for different catchments in Baden-Württemberg. You will then also investigate the temporal variability within these catchments by examining annual water balances. By performing the same analysis with both modelled and observational data, you will be able to investigate the functioning of the model and how well it represents the real world. For example, if the model produces too much streamflow in comparison to observations, | ||
| ** Data and methods ** | ** Data and methods ** | ||
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| The analysis uses model output data from the hydrological model RoGeR and observational data from several catchments in Baden-Württemberg. Averaged RoGeR inputs (e.g. precipitation), | The analysis uses model output data from the hydrological model RoGeR and observational data from several catchments in Baden-Württemberg. Averaged RoGeR inputs (e.g. precipitation), | ||
| The project can be divided into three parts. First, you will create a brief overview of the controls on the water balance at different time scales (long-term and yearly) which will serve as a conceptual basis of the project. Second, you will use observations from several catchments to explore hydrological behavior in real systems. Third, you will use the same methods to explore the behavior of RoGeR, check if modelled and observed data align, and explore the reasons if they do not. | The project can be divided into three parts. First, you will create a brief overview of the controls on the water balance at different time scales (long-term and yearly) which will serve as a conceptual basis of the project. Second, you will use observations from several catchments to explore hydrological behavior in real systems. Third, you will use the same methods to explore the behavior of RoGeR, check if modelled and observed data align, and explore the reasons if they do not. | ||
| ** Challenges ** | ** Challenges ** | ||
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| The project mostly involves data analysis and geospatial analysis and therefore you should have appropriate coding and GIS skills (e.g. Python or R, QGIS could be benefitial). You should also be comfortable with the management of large datasets. In addition, a good understanding of the catchment water balance and the hydrological modelling process are desirable. | The project mostly involves data analysis and geospatial analysis and therefore you should have appropriate coding and GIS skills (e.g. Python or R, QGIS could be benefitial). You should also be comfortable with the management of large datasets. In addition, a good understanding of the catchment water balance and the hydrological modelling process are desirable. | ||
| ** Supervision ** | ** Supervision ** | ||
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| Sebastian Gnann (University of Freiburg) and Markus Weiler (University of Freiburg) | Sebastian Gnann (University of Freiburg) and Markus Weiler (University of Freiburg) | ||
| ** Contact ** | ** Contact ** | ||
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| Sebastian Gnann | Sebastian Gnann | ||
| sebastian.gnann@hydrologie.uni-freiburg.de | sebastian.gnann@hydrologie.uni-freiburg.de | ||
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| Tel. +49 (0)761 / 203-9283 | Tel. +49 (0)761 / 203-9283 | ||
| ** Language ** | ** Language ** | ||
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| English or German | English or German | ||
| ** References ** | ** References ** | ||
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| Gupta, H. V., Wagener, T., & Liu, Y. (2008). Reconciling theory with observations: | Gupta, H. V., Wagener, T., & Liu, Y. (2008). Reconciling theory with observations: | ||