The roles of complex mechanical stratigraphy and syn-kinematic sedimentation in fold development: insights from discrete-element modelling and application to the Pico del Águila anticline (External Sierras, Southern Pyrenees)

Vidal-Royo, Oskar; Hardy, Stuart; Muñoz, J. A.

doi:10.1144/sp349.3

Cited by 19 publications

(17 citation statements)

References 27 publications

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“…These two sections show the same tectonic contraction (so would be numerical models (e.g. Strayer et al 2004;Vidal-Royo et al 2011;Hughes et al 2014). Analogue models show that the spacing and geometry of imbricate thrusts, together with their relative timing and activity, change depending on syn-kinematic sedimentation (Storti & McClay 1999;Bonnet et al 2008;Barrier et al 2013).…”

Section: Thrust Trajectories In Emergent Systemsmentioning

confidence: 77%

Syn-kinematic strata influence the structural evolution of emergent fold–thrust belts

Butler¹

2019

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Whether thrusts are ramp-dominated and form imbricate fans or run out onto the syn-orogenic surface, forming 'thrust-allochthons', is governed by the activity of secondary 'upper' detachments along the synorogenic surface, activations of which are inhibited by syn-kinematic sedimentation at the thrust front. In the northern Apennines, where thrust systems are ramp-dominated and form an emergent imbricate fan, synkinematic sedimentation was abundant and accumulated ahead and above each thrust. In the southern Apennines, the far-travelled Lagronegro allochthon achieved its high displacements (.65 km) while the foredeep basin received little sediment. The imbricate fan at the front of the main Himalayan arc developed within a foredeep that experienced high rates of syn-kinematic sedimentation. In contrast, further west, the Salt Range Thrust emerged into a distal, weakly developed foredeep with significantly reduced rates of sediment accumulation. Displacements were strongly localized onto this thrust (c. 25 km displacement) which activated an upper detachment along the syn-orogenic surface. It is an arrested thrust-allochthon. Lateral variations into the adjacent, ramp-dominated but still salt-detached, Jhelum fold-belt are marked by increases in syn-kinematic sedimentation. As sedimentation styles can vary in space and time, individual thrusts and thrust systems can evolve from being allochthon prone to imbricate dominated.From: HAMMERSTEIN, J. A., DI CUIA, R., COTTAM, M. A.,

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Section: Thrust Trajectories In Emergent Systemsmentioning

confidence: 77%

Syn-kinematic strata influence the structural evolution of emergent fold–thrust belts

Butler¹

2019

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“…They demonstrate that erosion facilitates and prolongs the activity of thrusts without changing their geometry (Raleigh and Griggs, 1963;Elliott, 1976;Johnson, 1981;Price and Johnson, 1982;Willemin, 1984;Merle and Abidi, 1995). They also highlight that sedimentation affects the geometry and dynamics of thrusts and folds (Tondji-Biyo, 1995;1999;Casas et al, 2001; Barrier et al, 2002;Gestain et al, 2004;Strayer et al, 2004;Pichot and Nalpas, 2009;Vidal-Royo et al, 2011). However, the influence of synkinematic deposits on compressive growth structures has not yet been systematically explored according to the different sedimentation modes (a slow or rapid sedimentation rate that is constant or changing in space and time) that can occur in natural systems.…”

Section: Introductionmentioning

confidence: 97%

Impact of synkinematic sedimentation on the geometry and dynamics of compressive growth structures: Insights from analogue modelling

et al. 2013

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International audienceAnalogue sandbox models have been set up to study the impact of synkinematic deposits on the geometry and evolution of single thrusts and folds according to different sedimentation modes (a slow or rapid sedimentation rate that is constant or changing in space and time) and rheological profiles (thin or thick sedimentary series, with or without a basal décollement level). A first series of experiments documents the influence of synkinematic deposits according to their sedimentation rate and the rheology of the prekinematic materials. A second series investigates the influence of changes in the sedimentation rate through time. A third one considers the influence of changes in the sedimentation rate in space. All these experiments suggest that the geometry and evolution of single compressive growth structures vary according to the sedimentation rate. The number and dip of their frontal thrust segments change with the ratio R between the sedimentation rate at the footwall of the faults and the uplift rate of their hanging wall. The latter is then more or less uplifted depending on the dip of the thrusts. As a result, the overall structure has either a fault-bend fold or a fault-propagation fold geometry. These rules are verified when the ratio R changes in space or through time. In addition, the rheological profile of the models also affects the geometry and evolution of compressive growth structures. Their structural style, as well as the synsedimentary splitting and steepening of the associated thrusts, varies according to the occurrence and strength of the brittle and ductile layers. According to this modelling study, the ratio R and its changes in space and time, along with the rheology of the deformed materials, are key parameters to better understand the geometrical and kinematical complexities of natural growth thrusts and folds and to improve their interpretation

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“…Hence, the displacement path, and kinematic evolution of the system can be recognized at any phase of the model (Vidal-Royo et al, 2011). For these reasons, this method has been used in many geological problems, especially involving the analysis of highstrain brittle deformation in the sedimentary cover such as normal faulting in layered sequences (Schöpfer et al, 2006(Schöpfer et al, , 2007a(Schöpfer et al, , 2007bEgholm et al, 2008;, fault bend folding (Strayer et al, 2004;Benesh et al, 2007), fault-propagation folding (Finch et al, 2003(Finch et al, , 2004Cardozo et al, 2005;Hardy andFinch 2006, 2007) (Hardy and Finch, 2005), and doubly vergent thrust wedges (Hardy et al, 2009), to name some examples.…”

Section: Discrete Element Methods -Demmentioning

confidence: 99%

Seismic Imaging of Salt-influenced Compressional Folds

Valencia¹,

Carolina²

2016

78th EAGE Conference and Exhibition 2016

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The roles of complex mechanical stratigraphy and syn-kinematic sedimentation in fold development: insights from discrete-element modelling and application to the Pico del Águila anticline (External Sierras, Southern Pyrenees)

Cited by 19 publications

References 27 publications

Syn-kinematic strata influence the structural evolution of emergent fold–thrust belts

Syn-kinematic strata influence the structural evolution of emergent fold–thrust belts

Impact of synkinematic sedimentation on the geometry and dynamics of compressive growth structures: Insights from analogue modelling

Seismic Imaging of Salt-influenced Compressional Folds

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