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The AAPG/Datapages Combined Publications Database

Journal of Sedimentary Research (SEPM)

Abstract


Journal of Sedimentary Research
Vol. 90 (2020), No. 12. (December), Pages 1706-1733
DOI: 10.2110/jsr.2020.012

Out-of-phase cyclical Previous HitsedimentNext Hit supply: A potential causal mechanism for generating stratigraphic asymmetry and explaining sequence stratigraphic spatial variability

R. Bruce Ainsworth, Adam J. Vonk, Paul Wellington, Victorien Paumard

Abstract

Although acknowledged to be a simplification, the rate of Previous HitsedimentNext Hit supply is usually assumed to be constant in sequence stratigraphic interpretations of clastic shelf systems. The simplified assumption taken in this work is that Previous HitsedimentNext Hit supply can be represented by sine curves linked to climate changes driven by Milankovitch cycles. Three orders of Previous HitsedimentNext Hit supply sine curves (amplitude and frequency scaled to order) are convolved with three orders of Milankovitch-forced eustatic sea-level sine curves and a constant rate of subsidence to generate curves for the ratio of rate of accommodation development to rate of Previous HitsedimentNext Hit supply (δ A S ). The relative-sea-level curve is then held constant whilst Previous HitsedimentNext Hit supply is systematically changed from being constant to being cyclical across the three orders of Milankovitch frequencies and being in-phase, and out-of-phase with the eustatic cycles by 90°, 180°, and 270°. For each scenario, stratal architecture is then represented for sixty consecutive parasequences (fifth-order, regressive–transgressive shelf transit cycles) by converting the δ A S curves into pseudo Previous HitthicknessNext Hit / sandstone fraction plots (TSF plots). Constant Previous HitsedimentNext Hit supply, in-phase Previous HitsedimentNext Hit supply, and 180°-out-of-phase Previous HitsedimentNext Hit supply produce symmetrical stratal geometries with equal periods of progradation, aggradation, and retrogradation. When Previous HitsedimentNext Hit-supply cycles are 90°-out-of-phase (supply peak occurs later than sea-level peak), stratal geometries are asymmetrical with progradational architectures being dominant. When Previous HitsedimentNext Hit-supply cycles are 270°-out-of-phase (supply peak occurs earlier than sea-level peak), stratal geometries are also asymmetrical but retrogradational architectures are dominant. These patterns are reproduced at all three orders of stratigraphic hierarchy (parasequence, sequence, and composite sequence). Comparison of these synthetic stratal geometries to real-world stratal geometries from Triassic to Neogene rocks across both the fifth-order (parasequence) and fourth-order (sequence) of stratal hierarchies suggests a consistently occurring asymmetrical, progradation-dominant motif. This indicates that 90°-out-of-phase Previous HitsedimentNext Hit supply (supply peak occurs later than sea-level peak) may be a common occurrence through geological time. The work also corroborates the findings of earlier workers and suggests that sequence stratigraphic surfaces can change nature along depositional strike due to out-of-phase Previous HitsedimentNext Hit supply and can thus also be diachronous. This work conceptually illustrates that Milankovitch climate-change-induced sinusoidal-Previous HitsedimentTop-supply cycles, out-of-phase with sinusoidal eustatic-sea-level cycles, may produce commonly observed asymmetrical stratal architectures and should be considered when invoking causal mechanisms for stratal architectures on clastic shelves.


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