Access the full text.
Sign up today, get DeepDyve free for 14 days.
Loading next page...
/lp/wiley/impact-of-transition-zones-variable-fluid-viscosity-and-anthropogenic-7KdBLkLwdi
References (37)
-
F. Magri, U. Bayer, A. Pekdeger, R. Otto, C. Thomsen, U. Maiwald (2009)
Salty groundwater flow in the shallow and deep aquifer systems of the Schleswig–Holstein area (North German Basin)Tectonophysics, 470
-
J. Hanor (1987)
Kilometre-scale thermohaline overturn of pore waters in the Louisiana Gulf CoastNature, 327
-
Y. Maystrenko, U. Bayer, M. Scheck‐Wenderoth (2005)
The Glueckstadt Graben, a sedimentary record between the North and Baltic Sea in north Central EuropeTectonophysics, 397
-
Alicia Wilson, C. Ruppel (2007)
Salt tectonics and shallow subseafloor fluid convection: models of coupled fluid‐heat‐salt transportGeofluids, 7
-
David Evans, J. Nunn (1989)
Free thermohaline convection in sediments surrounding a salt columnJournal of Geophysical Research, 94
-
V. Ranganathan, J. Hanor (1988)
Density-driven groundwater flow near salt domesChemical Geology, 74
-
(1902)
Der Untergrund von Oldesloe nebst einer kurzen Darstellung der Geschichte der ehemaligen Saline -
(2000)
Untersuchungsprogramm zur Ermittlung des Grundwasserdargebotes im Raum Lübeck - Teilprojekt Untertraverinne -
Claes Johnson (1992)
Finite element methods for flow problems -
M. Geluk (2005)
Stratigraphy and tectonics of Permo-Triassic basins in the Netherlands and surrounding areas -
F. Magri, U. Bayer, M. Tesmer, P. Möller, A. Pekdeger (2008)
Salinization problems in the NEGB: results from thermohaline simulationsInternational Journal of Earth Sciences, 97
-
David Evans, J. Nunn, J. Hanor (1991)
Mechanisms driving groundwater flow near salt domesGeophysical Research Letters, 18
-
G. Gabriel, R. Kirsch, B. Siemon, H. Wiederhold (2003)
Geophysical investigation of buried Pleistocene subglacial valleys in Northern GermanyJournal of Applied Geophysics, 53
-
M. Jackson, C. Talbot (1991)
A Glossary of Salt Tectonics -
U. Bayer, M. Scheck, M. Koehler (1997)
Modeling of the 3D thermal field in the northeast German basinGeologische Rundschau, 86
-
H. Heck (1949)
Der Grundwasserschatz in Schleswig-Holstein: Ein Wegweiser zur Wassererschließung -
M. Scheck, U. Bayer (1999)
Evolution of the Northeast German Basin — inferences from a 3D structural model and subsidence analysisTectonophysics, 313
-
(1985)
On the equations for the flow of concentrated salt solution through a porous medium -
Reinhard Baldschuhn, F. Binot, Stephanie Fleig, F. Kockel (2001)
Geotektonischer Atlas von Nordwest-Deutschland und dem - deutschen Nordsee-Sektor -
J. Sharp, T. Fenstemaker, C. Simmons, T. McKenna, J. Dickinson (2001)
Potential salinity-driven free convection in a shale-rich sedimentary basin: Example from the Gulf of Mexico basin in south TexasAAPG Bulletin, 85
-
Mark Williams, V. Ranganathan (1994)
Ephemeral thermal and solute plumes formed by upwelling groundwaters near salt domesJournal of Geophysical Research, 99
-
(2002)
Geophysikalische Erkundung eiszeitlicher Rinnen im südlichen Schleswig-Holstein -
M. Tesmer, P. Möller, S. Wieland, C. Jahnke, H. Voigt, A. Pekdeger (2007)
Deep reaching fluid flow in the North East German Basin: origin and processes of groundwater salinisationHydrogeology Journal, 15
-
S. Schoofs, U. Hansen (2000)
Depletion of a brine layer at the base of ridge-crest hydrothermal systemsEarth and Planetary Science Letters, 180
-
(1974)
Das Tertiär im Untergrund von Schleswig-Holstein (Das Nordwestdeutsche Tertiärbecken, Beitrag #5) -
(1993)
Stratigraphie und Gebirgsbau des Prätertiär (Paläozoikum und Mesozoikum) -
H. Diersch, O. Kolditz (1998)
Coupled groundwater flow and transport: 2. Thermohaline and 3D convection systemsAdvances in Water Resources, 21
-
D. Ophori (1998)
The significance of viscosity in density-dependent flow of groundwaterJournal of Hydrology, 204
-
Y. Maystrenko, U. Bayer, M. Scheck‐Wenderoth (2006)
3D reconstruction of salt movements within the deepest post-Permian structure of the Central European Basin System - the Glueckstadt GrabenNetherlands Journal of Geosciences - Geologie en Mijnbouw, 85
-
(2005)
Geologischer Profilschnitt durch das Arbeitsgebiet -
(1977)
Salzstrukturen, Erdöl und Kreidebasis in Schleswig-Holstein (Übersichtskarten zur Geologie von Schleswig-Holstein) -
P. Möller, S. Weise, M. Tesmer, M. Tesmer, P. Dulski, A. Pekdeger, Ulf Bayer, F. Magri (2008)
Salinization of groundwater in the North German Basin: results from conjoint investigation of major, trace element and multi-isotope distributionInternational Journal of Earth Sciences, 97
-
(1917)
Die Grundwasserverhältnisse der Stadt Lübeck und ihrer Umgebung -
(2004)
Geological and numerical modeling of geogenic salinization in the area of the Lübeck Basin -
S. Hassanizadeh (1988)
Modeling species transport by concentrated brine in aggregated porous mediaTransport in Porous Media, 3
-
(1996)
Zur Grundwasserversalzung in Schleswig - Holstein -
P. Patil, G. Vaidyanathan (1982)
Effect of variable viscosity on thermohaline convection in a porous mediumJournal of Hydrology, 57
- Publisher
- Wiley
- Copyright
- © 2009 Blackwell Publishing Ltd
- ISSN
- 1468-8115
- eISSN
- 1468-8123
- DOI
- 10.1111/j.1468-8123.2009.00242.x
- Publisher site
- See Article on Publisher Site
Abstract
In the Schleswig–Holstein region (S–H) of Germany, most observed near‐surface saline ground waters originate from dissolution of shallow salt domes. Previous numerical simulations of thermohaline flow clarified the major mechanisms controlling large‐scale density‐driven flow. It has been found that, in addition to topographically driven flow, gravitational and thermohaline convection are the primary mechanisms for extensive solute exchange between shallow and deep aquifers. Geological features such as glacial channels control recharge/discharge processes at the surface. Here we address several previously unresolved issues: (i) the impact of a permeable unit (transition zone) between the salt and adjacent units; (ii) the role of variable brine viscosity in affecting regional‐ (i.e. km‐) scale heat and mass patterns; and (iii) the influence of anthropogenic activities such as pumping stations on density‐driven flow. We found that geophysical factors play a major role in determining the dynamics of fluid processes. The transition zone significantly influences the flow field and the distribution of heat, slowing the formation of highly concentrated salty plumes. The impact of variable fluid viscosity on the coupled heat and brine flow is twofold. In a colder and highly concentrated environment, such as a shallow salt‐dome crest, it retards brine flow. In a less saline environment, variable fluid viscosity enhances thermally induced upward fluid flow. Groundwater extraction from production wells only affects brine and heat flow locally within the upper aquifers.
Journal
Geofluids – Wiley
Published: Aug 1, 2009