Stratigraphy and sedimentary evolution of a modern macro-tidal incised valley: An analogue for reservoir facies and architecture



McGhee, Claire, Muhammed, Dahiru ORCID: 0000-0001-5025-5456, Simon, Naboth, Acikalin, Sanem, Utley, James EP ORCID: 0000-0003-0397-5607, Griffiths, Joshua, Wooldridge, Luke, Verhagen, Iris TE ORCID: 0000-0003-1090-687X, van der Land, Cees and Worden, Richard H ORCID: 0000-0002-4686-9428
(2022) Stratigraphy and sedimentary evolution of a modern macro-tidal incised valley: An analogue for reservoir facies and architecture. SEDIMENTOLOGY, 69 (2). pp. 696-723.

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Abstract

<jats:title>Abstract</jats:title><jats:p>Incised valley fills are complex as they correspond to multiple sea‐level cycles which makes interpretation and correlation of stratigraphic surfaces fraught with uncertainty. Despite numerous studies of the stratigraphy of incised valley fills, few have focused on extensive core coverage linked to high fidelity dating in a macro‐tidal, tide‐dominated setting. For this study nineteen sediment cores were drilled through the Holocene succession of the macro‐tidal Ravenglass Estuary in north‐west England, UK. A facies and stratigraphic model of the Ravenglass incised valley complex was constructed, to understand the lateral and vertical stacking patterns relative to the sea‐level changes. The Ravenglass Estuary formed in five main stages. First, incision by rivers (<jats:italic>ca</jats:italic> 11 500 to <jats:italic>ca</jats:italic> 10 500 yrs <jats:sc>bp</jats:sc>) cutting through the shelf during lowstand, which was a period of fluvial dominance. Secondly, a rapid transgression and landward migration of the shoreline (10 500 to 6000 yrs <jats:sc>bp</jats:sc>). Wave action was dominant, promoting spit formation. The third stage was a highstand at <jats:italic>ca</jats:italic> 6000 to <jats:italic>ca</jats:italic> 5000 yrs <jats:sc>bp</jats:sc>, creating maximum accommodation and the majority of backfilling. The spits narrowed the inlet and dampened wave action. The fourth stage was caused by a minor fall of sea level (<jats:italic>ca</jats:italic> 5000 to <jats:italic>ca</jats:italic> 226 yrs <jats:sc>bp</jats:sc>), which forced the system to shift basinward. The fifth and final stage (226 yrs <jats:sc>bp</jats:sc> to present) involved the backfilling of the River Irt, southward migration of the northerly (Drigg) spit and merging of the River Irt with the Rivers Esk and Mite. The final stage was synchronous with the development of the central basin. As an analogue for ancient and deeply buried sandstones, most of the estuarine sedimentation occurred after transgression, of which the coarsest and cleanest sands are found in the tidal inlet, on the foreshore and within in‐channel tidal bars. The best‐connected (up to 1 km) reservoir‐equivalent sands belong to the more stable channels.</jats:p>

Item Type: Article
Uncontrolled Keywords: Connectivity, estuary, incised-valley, Ravenglass, sandstone reservoir quality, sequence stratigraphy, tide-dominated
Divisions: Faculty of Science and Engineering > School of Environmental Sciences
Depositing User: Symplectic Admin
Date Deposited: 11 Oct 2021 07:42
Last Modified: 04 Sep 2023 02:40
DOI: 10.1111/sed.12922
Related URLs:
URI: https://livrepository.liverpool.ac.uk/id/eprint/3139963

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