--> From Quantitative 3-D Seismic Stratigraphy to 3-D Sequence Stratigraphy: Insights Into the Vertical and Lateral Variability of Basin-Margin Depositional Systems at Different Stratigraphic Orders
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From Quantitative 3-D Previous HitSeismicNext Hit Stratigraphy to 3-D Previous HitSequenceNext Hit Stratigraphy: Insights Into the Vertical and Lateral Variability of Basin-Margin Depositional Systems at Different Stratigraphic Orders

Victorien Paumard1, Julien Bourget1, R. Bruce Ainsworth2, Tobias Payenberg2, Annette George1, Simon Lang1


1The University of Western Australia;
2Chevron Australia Pty. Ltd.


May 19-22 20192019 AAPG Annual Convention and Exhibition, San Antonio, Texas

Posted: June 30, 2019

Abstract

A major challenge of Previous HitsequenceNext Hit stratigraphy is to recognize objectively different orders of stratigraphic surfaces and sequences. Their identification is commonly dependent of the resolution of the data used, its dimension (2D vs. 3D) or the criteria chosen to select Previous HitsequenceNext Hit Previous HitboundariesNext Hit. In this study, we propose an innovative data-driven approach to develop Previous HitsequenceNext Hit stratigraphic frameworks across different stratigraphic orders.

High-quality 3D Previous HitseismicNext Hit data are used to interpret an Early Cretaceous shelf margin, the Lower Barrow Group (LBG; North West Shelf, Australia). The method is based on full-volume Previous HitseismicNext Hit interpretation techniques that integrate the 3D variability of the data when identifying Previous HitseismicNext Hit unconformities. A 5th order, high-resolution Previous HitseismicNext Hit stratigraphic framework was constructed (73 interpreted clinothems with a duration of ~63,000 yrs each).

The computation of high-frequency shelf-edge trajectory angle (Tse) curves on selected Previous HitseismicNext Hit cross-sections was used to objectively pick Previous HitsequenceNext Hit stratigraphic surfaces. The definition of stratigraphic sequences (4th order) and composite stratigraphic sequences (3rd order) via this workflow is then used to (1) quantify the vertical and lateral variability in stratal stacking patterns; and (2) discriminate the allogenic and autogenic controls responsible for this 4D variability at multiple timescales.

The results show that the 4th to 5th order stratigraphic architecture of the LBG results from the interplay between short-term glacio-eustasy (Milankovitch cycles of ~100,000 yrs) and sediment supply (location of fluvial feeder systems along the margin). At the 3rd order, tectonic subsidence overprinted the eustatic signal in the main regional depocenter and accelerated the rates of accommodation creation. However, identification of long-term glacio-eustatic Milankovitch cycles (~400,000 yrs) in coeval sequences outside this depocenter, where the rates of accommodation creation due to rift-related subsidence are more limited, also suggests a low-frequency eustatic control.

Quantitative 3D Previous HitseismicNext Hit stratigraphy provides an observation-based and model-independent tool allowing the definition of stratigraphic sequences with results reproducible by different stratigraphers. It represents a first step towards the creation of 3D Previous HitsequenceTop stratigraphic workflows that could improve the prediction of stratigraphic patterns and facies relationships (source, reservoir, seal distribution) across continental margins.

AAPG Datapages/Search and Discovery Article #90350 © 2019 AAPG Annual Convention and Exhibition, San Antonio, Texas, May 19-22, 2019