Effect of Alpine Karst on the Hydrology of the Berchtesgadener Ache Basin: a Comprehen- Sive Summary of Karst Research in the Berchtesgaden Alps

Effect of Alpine Karst on the Hydrology of the Berchtesgadener Ache Basin: a Comprehen- Sive Summary of Karst Research in the Berchtesgaden Alps

Research eco.mont - Volume 3, Number 1, June 2011 ISSN 2073-106X print version 19 ISSN 2073-1558 online version: http://epub.oeaw.ac.at/eco.mont Effect of Alpine karst on the hydrology of the Berchtesgadener Ache basin: a comprehen- sive summary of karst research in the Berchtesgaden Alps Gabriele Kraller, Ulrich Strasser & Helmut Franz Keywords: karst, tracer, isotope, groundwater flow, distributed water modelling, regional scale, integrated water resource management Abstract Profile The Berchtesgaden Alps are situated in the Northern Limestone Alps, character- Protected Area ized by individual mountain plateaus and ridges in close proximity to each other, intersected by valleys, with an altitudinal gradient of 2 100 meters. The limestone has Berchtesgaden National Park been exposed to dissolution processes since the Cretaceous, leading to a massive karstified aquifer with a wide range of subsurface flow channels. There are hundreds of springs as groundwater recharge locations, feeding the seven rivers of the region Mountain range that contribute to the Danube watershed. Several studies were conducted to exam- ine the hydro-geological conditions and the resulting groundwater flow. This paper Alps aims to evaluate and summarize research in the basin describing groundwater flow to identify the main drainage direction, travel times, spring dynamics and possible Country subsurface redistribution in the individual mountain ranges and the whole basin. To this end, we evaluate several tracer experiments, two isotope studies and a spring Germany database. The tracer experiments are generating knowledge about flow directions in the individual mountain ranges, groundwater redistribution, water storage and mean travel times. Five experiments prove increased groundwater flow remaining within a valley and four experiments indicate groundwater redistribution through mountain ranges. The isotope studies indicate potential water storage in the Wimbach valley of an estimated 100 x 106 to 470 x 106 m3 and mean transit times of about four years. The analysis of the spring database focuses on locations and discharge classifica- tion. Overall, there are 289 springs recorded in the spring database, distributed from 600 to over 2 000 m altitude, with major springs at the northern base of the mountains Hochkalter, Watzmann and at the north shore of lake Königssee. The conclusion summarizes the effect of the karst aquifer on the hydrology of the region. The outlook introduces current research within the area and the distributed water balance modelling. Theoretical background The Northern Limestone Alps are characterized by massive layers of dolomite and banked limestone, formed through sedimentation processes during the Triassic formation (Langenscheidt 1994). Alpine fold- ing during the Cretaceous led to a typical arrangement of interfaces and joints. Postglacial ice covers and their movement shaped present day mountain ranges and plateaus and the valleys in between. With the lift- ing of the Alps, the soluble limestone was exposed to dissolution processes leading to the generation of subsurface pathways along the interfaces (karst). The main characteristic of a karst aquifer is that it consists of two components, the rock matrix and the conduits inbetween (Atkinson 1977; Bakalowicz 2005; Kiraly 2003; Sauter et al. 2006; Teutsch & Sauter 1991; White 2002). White (2003) describes fractures as a third com- ponent of karst aquifers. This leads to a broad field of hydraulic parameters and unknown boundary con- ditions, which form the main challenge of describing the groundwater flow in the existing approaches (Ki- raly 2003; White 2002; Sauter et al. 2006). Atkinson Figure 1 – Berchtesgaden Alps: mountain ranges and main rivers. Research 20 (1977) found for the Mendip Hills in Great Britain derstand hydrological processes within the Berchtes- that the majority of the water is transported through gaden watershed, to gain more information about enlarged conduits. The specific geomorphologic-geo- water storage in winter and summer and to predict fu- logical structure produces the effect that the surface ture water availability and dynamics by performing cli- drainage basin differs from the groundwater basin be- mate impact scenarios. The overall aim is to improve cause unknown underground flow channels lead to a hydrological modelling in karst-dominated catch- redistribution of infiltration water across the bound- ments for integrated water resource management. ary. This makes it difficult to quantify the amount of the redistributed water. Site description Mountain massifs can be seen as lifted aquifers char- acterized by high altitudinal gradients and inclined General stratification. The head difference between recharge The Berchtesgaden Alps are situated in the Northern area and springs is the primary driving force for the Limestone Alps in the southeast of Germany in the movement of water through the aquifer (White 2003). Federal State of Bavaria. Most of the area is part of One can assume that groundwater flow in Alpine Berchtesgaden Biosphere Reserve. Its core and buffer catchments is increased, as they consist of banked zone is Berchtesgaden National Park (Berchtesgaden karstified limestone, the increased groundwater flow NP; IUCN Category II) covering an area of 210 km2. may even be additionally strengthened and redistribu- tion processes may take place at the subbasin scale and Geology and geomorphology affect receiving water courses in neighbouring Alpine The Berchtesgaden Alps can be seen as a geomorpho- valleys. However, in terms of sustainable water man- logic unit. The mountain ranges are shaped as plateaus agement, Alpine basins are the origin of large lowland and ridges in close proximity (Figure 1). Three val- watersheds, contributing with spring and surface water leys (Klausbach valley, Wimbach valley and Königssee to brooks and rivers that in turn contribute to defined valley) stretch from south to north, separating four lowland river systems. Therefore, it is indispensible mountain massifs. Dominant rock formations are to understand the characteristics of subsurface water Triassic Dachstein limestone and Ramsau dolomite, flow and its effect on the regional hydrology. More- whereas Jurassic and Cretaceous rock series are also over, system understanding is absolute necessary to present. The banked limestone with a layer thickness predict future changes in the light of climate change. of up to 1 000 metres, on top of 300 metres of dolo- Many studies in karstified areas focus on small-scale mite, reaches an altitude of up to 2 100 m. The three effects of karst conduits by examining spring hy- main tectonic units in the area are arranged in such a drographs, chemographs and tracer breakthrough way that the base Tirolicum is covered by the Lower curves – to define the size and the characteristics of Juvavicum, which is itself beneath the Upper Juvavi- one individual spring aquifer (Birk et al. 2004; Bonacci cum. Alpine orogenic processes have produced the 1993; Einsiedl et al. 2005; Geyer et al. 2008; Grasso et typical slope and inclined stratification of the existing al. 2003; Hauns et al. 2001; Kovács et al. 2005; Smart rock formations (Fischer 2005; Langenscheidt 1994). 1988). Other approaches concentrate on karst genesis The soluble limestone was exposed to karstification or theoretical conduit flow (Sauter et al. 2006; White processes since the Alpine thrust, which took place in 2002). Those studies do not provide answers to ques- different phases. Typical karst phenomena in the re- tions about karst effects on the comprehensive water gion are the presence of sinkholes, basins, dry stream balance of an Alpine headwater catchment. Ques- beds, caves and furrows. An exceptional characteristic tions remain: how much water redistributes from one is the Wimbach valley, which is filled with 300 m thick subbasin (valley) to another through flow channels in layer of glacial deposits, consisting mainly of dolomite mountain massifs? Can we quantify groundwater flow rock that forms a porous aquifer. in karstified mountains? This review paper summarizes all previous research in River hydrology the study area with a focus on the water balance in The rivers Klausbach and Wimbach and Königsseer the region. It aims to emphasize all outcomes indicat- Ache drain three parallel valleys stretching from south ing karst influence for the whole watershed or single to north (Figure 1). The Klausbach is a sinking stream subbasins. This knowledge provides profound insights during low flow conditions and the Wimbach is only into how the system is functioning and is the basis for emerging at a dam in the Wimbachtal that restrains the the current research project in the Berchtesgaden wa- glacial deposits. The Königsseer Ache is draining lake tershed describing the water balance, with a focus on Königssee. The Klausbach, draining the most western snow and groundwater storage, using the determinis- valley and later called Ramsauer Ache, receives the tic model WaSiM-ETH (Schulla & Jasper 2007). The Wimbach from the south, plus the Bischofswiesener outcome of this paper helps to improve the distrib- Ache from a northerly direction. In Berchtesgaden, uted model WaSiM-ETH for the area with respect to the Ramsauer Ache and Königsseer Ache together groundwater flow and its influence on the hydrology form the Berchtesgadener Ache which flows north. of the basin. The new model set-up will help to un- Further down, the Almbach and Rothmannbach Gabriele Kraller, Ulrich Strasser

View Full Text

Details

  • File Type
    pdf
  • Upload Time
    -
  • Content Languages
    English
  • Upload User
    Anonymous/Not logged-in
  • File Pages
    10 Page
  • File Size
    -

Download

Channel Download Status
Express Download Enable

Copyright

We respect the copyrights and intellectual property rights of all users. All uploaded documents are either original works of the uploader or authorized works of the rightful owners.

  • Not to be reproduced or distributed without explicit permission.
  • Not used for commercial purposes outside of approved use cases.
  • Not used to infringe on the rights of the original creators.
  • If you believe any content infringes your copyright, please contact us immediately.

Support

For help with questions, suggestions, or problems, please contact us