Crustal Thickness and Glacially Formed Topographic Relief of the Southern Scandes Mountains.
Abstract
New constraints for studies of topography and uplift in southern Norway have been added by a recent crustal scale refraction project. Magnus-Rex (Mantle investigation of Norwegian uplift Structure, refraction experiment) recorded three ~400 km long active source seismic profiles across the high southern Scandes Mountains. The goal of the project is determine crustal thickness and establish whether these mountains are supported at depth by a crustal root or by other processes. Uplift and support of the high topography of the southern Scandes Mountains is part of the TopoEurope initiative, a focussed study on the 4D evolution of topography. The southern Scandes Mountains were formed during the Caledonian Orogeny around 440 Ma. These mountains, which reach elevations of up to ~2.5 km, are comprised of one or more palaeic (denudation) surfaces of rolling relief, that are incised by fluvial and glacial erosion. Extreme vertical glacial incision of up to 1000 m cuts into the surfaces in the western fjords, while the valleys of eastern Norway are more fluvial in character. Climatic controls on topography here are the Neogene - Recent effects of rebound due to removal of the Fennoscandian ice sheet and isostatic rebound due to incisional erosion. However, unknown tectonic uplift mechanisms are also in effect, and separating the tectonic and climate-based vertical motions here is difficult. Sediment has been removed by the formation of the palaeic surfaces and uplift measurements cannot be directly related to present elevations. Estimates so far have indicated that incisional erosion has a small effect of ~500 m on surface elevation, while the long term effect of the removal of the Fennoscandian ice sheet produces an uplift of around 1 mm per year. Results from Magnus-Rex indicate the crust beneath the high mountains is up to 40 km thick. This thickness implies that the high elevations of the southern Scandes Mountains are not entirely compensated under Airy isostasy and other mechanisms for uplift and sustained topography relief must be in effect. We relate new crustal thickness measurements to observed topography to quantify how much of the present elevation of the southern Scandes Mountains can be accounted for by Airy isostasy. Density constraints from seismic velocities and elastic thickness measurements of the lithosphere allow more accurate models of exhumation in southern Norway. This new understanding of crustal structure can be used to help separate the climatic and tectonic effects on landscape evolution of the southern Scandes Mountains.
- Publication:
-
AGU Fall Meeting Abstracts
- Pub Date:
- December 2008
- Bibcode:
- 2008AGUFM.T53A1914S
- Keywords:
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- 7205 Continental crust (1219);
- 8105 Continental margins: divergent (1212;
- 8124);
- 8120 Dynamics of lithosphere and mantle: general (1213);
- 8175 Tectonics and landscape evolution;
- 8177 Tectonics and climatic interactions