Effects of reactivated extensional basement faults on structural evolution of fold-and-thrust belts: Insights from numerical modelling applied to the Kopet Dagh Mountains

Effects of reactivated extensional basement faults on structural evolution of fold-and-thrust belts: Insights from numerical modelling applied to the Kopet Dagh Mountains

The structural evolution of basement-involved, or thick-skinned, fold-and-thrust belts is often affected by preexisting, inherited extensional faults within the basement. Here, a crustal-scale two-dimensional finite difference model with a visco-elasto-brittle/plastic rheology is applied to investig...

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Bibliographic Details
Published in:Tectonophysics Vol. 746; pp. 493 - 511
Main Authors: Ruh, Jonas B., Vergés, Jaume
Format: Journal Article
Language:English
Published: Amsterdam Elsevier B.V 30-10-2018
Elsevier BV
Subjects:
Activation
Basement-involvement
Basements & cellars
Basins
Belts
Compression
Cross cutting
Crustal strength
Deformation
Diorite
Erosion
Erosion rates
Evolution
Fault weakening
Faults
Finite difference method
Geological faults
Inversion
Kopet Dagh
Mass movement
Mathematical models
Modelling
Mountains
Numerical analysis
Numerical modelling
Plate tectonics
Quartzite
Rheological properties
Rheology
Shear zone
Structural engineering
Tectonic inversion
Tectonics
Thick-skinned
Thrust bearings
Two dimensional models
Uplift
Fault weakening
Thick-skinned
Tectonic inversion
Numerical modelling
Basement-involvement
Kopet Dagh
Crustal strength
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Summary:The structural evolution of basement-involved, or thick-skinned, fold-and-thrust belts is often affected by preexisting, inherited extensional faults within the basement. Here, a crustal-scale two-dimensional finite difference model with a visco-elasto-brittle/plastic rheology is applied to investigate the formation of fold-and-thrust belts as a result of tectonic inversion, from intracontinental extension to compression. We examine the influence of frictional strain weakening, varying surface process intensity and different crustal rheologies. Intense strain weakening results in narrow and deep basins with wide shear zone spacing during the extension phase and fault reactivation and localized uplift during inversion. Little weakening of shear zones results in thrusts cross-cutting pre-existing normal faults and the development of newly-formed thrusts in distal parts of the fold-and-thrust belt during inversion. Enhanced surface mass movement localizes deformation and uplift in the central part of mountain belts. Implementation of a weak upper crust (quartzite) leads to less localized deformation compared to a strong crust (quartz-diorite). We compare modelling results to the basement-involved Kopet Dagh Mountains, NE Iran, and discuss potential lateral variation of fault reactivation and erosion rates being responsible for deeper tectonic exhumation in the eastern part of the mountain belt, relative to the West and Central Kopet Dagh. •Crustal-scale numerical models test strain weakening effect on tectonic inversion.•Basin formation and fault reactivation is strongly dependent on weakening amount and surface processes.•Results help understanding lateral variation of exhumation in the Kopet Dagh Mountains, NE Iran.
ISSN:0040-1951
1879-3266
DOI:10.1016/j.tecto.2017.05.020