Analogue modelling of thrust systems: Passive vs. active hanging wall strain accommodation and sharp vs. smooth fault-ramp geometries

We present new analogue modelling results of crustal thrust-systems in which a deformable (brittle) hanging wall is assumed to endure passive internal deformation during thrusting, i.e. exclusively as a consequence of having to adapt its shape to the variable geometry of a rigid footwall. Building o...

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Bibliographic Details
Published in:Journal of structural geology 2017-06, Vol.99, p.45-69
Main Authors: Rosas, F.M., Duarte, J.C., Almeida, P., Schellart, W.P., Riel, N., Terrinha, P.
Format: Article
Language:English
Subjects:
Analogue modelling
Basal velocity discontinuity
Hanging wall passive deformation
Thrust ramp geometry
Thrust-systems
Thrust-wedge morpho-structural configuration
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Summary:We present new analogue modelling results of crustal thrust-systems in which a deformable (brittle) hanging wall is assumed to endure passive internal deformation during thrusting, i.e. exclusively as a consequence of having to adapt its shape to the variable geometry of a rigid footwall. Building on previous experimental contributions, we specifically investigate the role of two so far overlooked critical variables: a) concave-convex (CC) vs. flat-ramp-flat (FRF) thrust ramp geometry; and b) presence vs. absence of a basal velocity discontinuity (VD). Regarding the first variable, we compare new results for considered (CC) smoother ramp types against classical experiments in which (FRF) sharp ramp geometries are always prescribed. Our results show that the considered sharp vs. smooth variation in the thrust-ramp geometry produces important differences in the distribution of the local stress field in the deformable hanging wall above both (lower and upper) fault bends, with corresponding styles of strain accommodation being expressed by marked differences in measured morpho-structural parameters.
Regarding the second variable, we for the first time report analogue modelling results of this type of experiments in which basal VDs are experimentally prescribed to be absent. Our results critically show that true passive hanging wall deformation is only possible to simulate in the absence of any basal VD, since active shortening accommodation always necessarily occurs in the hanging wall above such a discontinuity (i.e. above the lower fault bend). In addition, we show that the morpho-structural configuration of model thrust-wedges formed for prescribed VD absence conditions complies well with natural examples of major overthrusts, wherein conditions must occur that approximate a frictionless state along the main basal thrust-plane. •Analogue modelling of thrust systems comprising a deformable (brittle) hanging wall and a rigid footwall.•Hanging wall strain accommodation as a function of variable (flat-ramp-flat vs. concave-convex) footwall ramp geometry.•Passive vs. active hanging wall strain accommodation.•Insight resulting from the comparison with natural examples of major overthrusts.
ISSN:0191-8141
1873-1201
DOI:10.1016/j.jsg.2017.05.002