Steven J. Ings scite author profile

Salt flows downslope, irrespective of overburden. In salt basins on passive margins, the salt will tilt and flow towards the ocean immediately after continental rifting has ended due to thermal subsidence. Using real examples, as well as physical and numerical models, tilting is shown to be relatively rapid, enhanced by isostatic rebound updip and loading downdip where salt pools and inflates behind an outer high. In the Santos, Campos and Kwanza basins, this outer high is represented by an embryonic mid-Atlantic ridge, amplified in height by the differential weight of the inflating salt. Widespread extension and translation of overburden, utilizing both seaward- and landward-dipping normal faults, characterizes the early evolution of the inboard region. Inflation and contraction occur outboard, the effects of which tend to expand in a landward direction over time. Rapid accumulation of salt implies wholesale dewatering of pre-salt sediments, the water possibly permeating the salt once it has reached a burial depth of c. 3 km. The process of thermal subsidence, salt drainage and isostatic amplification is an efficient mechanism for moving sediment on passive margins tens of kilometres seaward during a relatively short period and helps explain why great thicknesses of salt can accumulate there in the first place.

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Salt tectonics driven by differential sediment loading: stability analysis and finite‐element experiments

Gemmer

et al. 2004

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At many continental margins, di¡erential sediment loading on an underlying salt layer drives salt deformation and has a signi¢cant impact on the structural evolution of the basin.We use 2-D ¢niteelement modelling to investigate systems in which a linear viscous salt layer underlies a frictionalplastic overburden of laterally varying thickness. In these systems, di¡erential pressure induces the £ow of viscous salt, and the overburden experiences updip deviatoric tension and downdip compression. A thin-sheet analytical stability criterion for the system is derived and is used to predict conditions under which the sedimentary overburden will be unstable and fail, and to estimate the initial velocities of the system.The analytical predictions are in acceptable agreement with initial velocity patterns of the numerical models.In addition to initial stability analyses, the numerical model is used to investigate the subsequent ¢nite deformation. As the systems evolve, overburden extension and salt diapirism occur in the landward section and contractional structures develop in the seaward section.The system evolution depends on the relative widths of the salt basin and the length scale of the overburden thickness variation. In narrow salt basins, overburden deformation is localised and characterised by high strain rates, which cause the system to reach a gravitational equilibrium and salt movement to cease earlier than for wide salt basins. Sedimentation enhances salt evacuation by maintaining a di¡erential pressure in the salt. Continued sedimentary ¢lling of landward extensional basins suppresses landward salt diapirism. Sediment progradation leads to seaward propagation of the landward extensional structures and depocentres. At slow sediment progradation rates, the viscous £ow can be faster than the sediment progradation, leading to e⁄cient salt evacuation and salt weld formation beneath the landward section. Fast sediment progradation suppresses the viscous £ow, leaving salt pillows beneath the prograding wedge.

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Dynamic modelling of passive margin salt tectonics: effects of water loading, sediment properties and sedimentation patterns

2005

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We investigate the evolution of passive continental margin sedimentary basins that contain salt through two -dimensional (2D) analytical failure analysis and plane-strain ¢nite-element modelling. We expand an earlier analytical failure analysis of a sedimentary basin/salt system at a passive continental margin to include the e¡ects of submarine water loading and pore £uid pressure. Seaward thinning sediments above a weak salt layer produce a pressure gradient that induces Poiseuille £ow in the viscous salt.We determine the circumstances under which failure at the head and toe of the frictional^plastic sediment wedge occurs, resulting in translation of the wedge, landward extension and seaward contraction, accompanied by Couette £ow in the underlying salt.The e¡ects of water: (i) increase solid and £uid pressures in the sediments; (ii) reduce the head to toe di¡erential pressure in the salt and (iii) act as a buttress to oppose failure and translation of the sediment wedge.The magnitude of the translation velocity upon failure is reduced by the e¡ects of water.The subsequent deformation is investigated using a 2D ¢nite-element model that includes the e¡ects of the submarine setting and hydrostatic pore pressures.The model quantitatively simulates a 2D approximation of the evolution of natural sedimentary basins on continental margins that are formed above salt. Sediment progradation above a viscous salt layer results in formation of landward extensional basins and listric normal growth faults as well as seaward contraction. At a later stage, an allochthonous salt nappe overthrusts the autochthonous limit of the salt.The nature and distribution of major structures depends on the sediment properties and the sedimentation pattern. Strain weakening of sediment favours landward listric growth faults with formation of asymmetric extensional depocentres. Episodes of low sediment in£ux, with partial in¢ll of depocentres, produce local pressure gradients in the salt that result in diapirism. Diapirs grow passively during sediment aggradation.

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An investigation of salt tectonic structural styles in the Scotian Basin, offshore Atlantic Canada: 1. Comparison of observations with geometrically simple numerical models

Albertz¹,

Beaumont

Shimeld

et al. 2010

Tectonics

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[1] Three primary salt tectonic structural styles of the Scotian Basin are compared with plane strain finite element models in order to investigate their origin. Here, we focus on simplified model salt basins with initial rectangular cross-sectional geometries and follow their evolution in the context of tectonic and parametric thermal subsidence and under various sedimentation regimes. Structural style A, an open-ended roho system with a synkinematic wedge, is reproduced by models including deltaic progradation and seaward spreading/ gliding of sediments above a salt detachment. Structural style B, a linked salt tectonic system with landward regional normal faults and allochthonous salt sheets climbing seaward over Late Cretaceous and Paleogene strata, is shown to be a consequence of early aggradation followed by progradation. Structural style C is characterized by salt diapirs and intervening minibasins and is reproduced by models with Rayleigh-Taylor instabilities requiring compaction driven density inversions, weak sediments, and initial perturbations of the overburden-salt interface.

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Some consequences of mechanical stratification in basin-scale numerical models of passive-margin salt tectonics

Albertz

Ings

2012

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Two-dimensional plane-strain numerical experiments illustrate the effects of variable evaporite viscosity and embedded frictional-plastic sediment layers on the style of salt flow and associated deformation of the sedimentary overburden. Evaporite viscosity exerts a first-order control on the salt flow rate and the style of overburden deformation. Nearly complete evacuation of low-viscosity salt occurs beneath expulsion basins, whereas significant salt is trapped when viscosity is high. Embedded frictional-plastic sediment layers with yield strength partition salt flow and develop transient contractional structures (folds, thrust faults and folded faults) in a seaward salt-squeeze flow regime. Multiple internal sediment layers reduce the seaward salt flow during sediment aggradation, leaving more salt behind to be remobilized during subsequent progradation. This produces more seaward extensive allochthonous salt sheets. If there is a density difference between the embedded layers and the surrounding salt, then the embedded layers fractionate during deformation and either float to the surface or sink to the bottom, creating a thick zone of pure halite. Such a process of ‘buoyancy fractionation’ may partially explain the apparent paradox of layered salt in autochthonous salt basins and pure halite in allochthonous salt sheets.Supplementary material:Animated gif files of the model results are available at http://www.geolsoc.org.uk/SUP18500.

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Steven J. Ings

Salt tectonics on passive margins: examples from Santos, Campos and Kwanza basins

Salt tectonics driven by differential sediment loading: stability analysis and finite‐element experiments

Dynamic modelling of passive margin salt tectonics: effects of water loading, sediment properties and sedimentation patterns

An investigation of salt tectonic structural styles in the Scotian Basin, offshore Atlantic Canada: 1. Comparison of observations with geometrically simple numerical models

Some consequences of mechanical stratification in basin-scale numerical models of passive-margin salt tectonics

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