Summary
The Devonian sedimentary basins of Northern Scotland illustrate the different processes of inversion along reactivated frontal and lateral thrust ramps, and the importance of strike-slip fault movements to late and post-Caledonian tectonics. The basins of the West Orkneys and West Shetland, west of the Great Glen Fault developed by collapse of thickened Caledonian crust during the Devonian. The basins extended in a NW-SE direction on dominantly SE-dipping faults, which curve and become parallel to the earlier Caledonian fabric at depth. The Caledonian structures developed a crustal anisotropy which was subsequently reworked during the later Palaeozoic and Mesozoic by extensional and compressional movements. Hence in the West Orkney and Minches basins, Caledonian structures influenced the kinematics of Early to Middle Old Red Sandstone extension, later (Devonian and Permo-Carboniferous) compression, Mesozoic extension and later Mesozoic-Tertiary compression. During basin extension, minor inversion of early listric normal faults occurred within the basin sediments, driven by gravitational gliding down tilted fault blocks. SE of the Great Glen Fault in eastern Shetland and possibly also the Inner Moray Firth, basins were affected by NE-SW extension during Middle to Upper Devonian times. This is possibly a result of sinistral strike-slip displacements on the Great Glen-Walls Boundary Fault system. This strike-slip episode may have been responsible for inversion of the earlier and more regionally widespread Lower and Middle Devonian basins formed by NW-SE extension. Localized zones of folding in Caithness and the Orkney Islands and wide zones of more intense folding in western Shetland are thought to be related to this deformation. Late Palaeozoic Variscan dextral strike-slip displacements juxtaposed basins along the Great Glen-Walls Boundary fault system which have distinct stratigraphies and structural evolutions and formed separately to the east and west of these faults. This strike-slip deformation inverted basins both to the east and west of the Great Glen Fault. In the East Shetland basins it produced local zones of overturned beds above oblique and frontal ramps. Further subsequent dextral movements in the Mesozoic produced pull-apart basins in the Moray Firth and East Orkneys.
Evolutionary models that have been proposed for the Pyrenean orogenic belt involve gravitational gliding of major thrust sheets to both the north and south of an uplifted central Axial Zone. It has been suggested by previous workers that uplift is a result of Alpine compression, or long lived strike slip movement on the North Pyrenean Fault. We critically assess these models and propose a new model based on the generation of a thin‐skinned, linked thrust system, due to Alpine collision of Iberia and Europe. Pyrenean Alpine tectonics is dominated by southward thrusting on a major sole fault dipping north at approximately 6° within Hercynian basement. Northerly directed thrusts of the North Pyrenean Zone and Northern Folded Foreland are backthrusts from this sole fault. A total orogenic shortening of 106 km in the central Pyrenees was achieved between the Palaeocene and Oligocene at a time‐averaged rate of 0.62 cm yr−1. A thin‐ skinned model requires that the North Pyrenean Fault is truncated by both northward and southward moving thrusts and occurs in the footwall of the sole fault some 60km north of its present surface trace.
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