The impact of fine-scale turbidite channel architecture on deep-water reservoir performance

Alpak, Faruk O.; Barton, Mark D.; Naruk, Stephen J.

doi:10.1306/04021211067

Cited by 37 publications

(38 citation statements)

References 26 publications

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“…Integrated subsurface characterization, modeling, and flow simulation studies have evaluated the effect of facies architecture on channelized reservoir connectivity and performance (Larue and Hovadik, 2006;Stright, 2006;Labourdette, 2007;Stewart et al, 2008;Funk et al, 2012;Alpak et al, 2013). For example, Larue and Hovadik (2006) simulated oil production with water injection in simple 3D geostatistical models of channelized reservoirs.…”

Section: Submarine-channel Reservoir Characterizationmentioning

confidence: 99%

“…For example, Larue and Hovadik (2006) simulated oil production with water injection in simple 3D geostatistical models of channelized reservoirs. They found that fine-grained facies, such as mud-rich turbidites and debrites draping channel floors, decreased connectivity (Larue and Hovadik, 2006; see also Stright, 2006;Labourdette, 2007;Stewart et al, 2008;Li and Caers, 2011;Alpak et al, 2013). Stewart et al (2008) performed flow simulations on a model describing the submarine-channel facies architecture of the MiocenePliocene Capistrano Formation, southern California, to evaluate the effect of heterogeneity and connectivity on hydrocarbon recovery.…”

Section: Submarine-channel Reservoir Characterizationmentioning

confidence: 99%

“…the margins (Beaubouef et al, 1999;Pyles et al, 2010;Hubbard et al, 2014). Channel fills are also associated with scour surfaces draped by variable mudstone-rich units (Barton et al, 2010;Alpak et al, 2013;Macauley and Hubbard, 2013).…”

Section: Introductionmentioning

confidence: 99%

“…We illustrate the incising-to-aggrading trajectory of a channel system in a 3D surface-based stratigraphic forward model. The model records the 3D stacking patterns of a channel system, which is a principal control on fluid flow behavior during hydrocarbon production (e.g., Larue and Hovadik, 2006;Stright, 2006;Labourdette, 2007;Stewart et al, 2008;Funk et al, 2012;Alpak et al, 2013). We review the implications of channel-system stratigraphic evolution for channelized reservoir heterogeneity, connectivity, and performance.…”

Section: Introductionmentioning

confidence: 99%

See 3 more Smart Citations

The Stratigraphic Record of Submarine-Channel Evolution

Covault¹,

Sylvester²,

Hubbard³

et al. 2016

TSR

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Section: Submarine-channel Reservoir Characterizationmentioning

confidence: 99%

Section: Submarine-channel Reservoir Characterizationmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

See 2 more Smart Citations

The Stratigraphic Record of Submarine-Channel Evolution

Covault¹,

Sylvester²,

Hubbard³

et al. 2016

TSR

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“…Pringle et al 2010;Stright et al 2014). However, although channel-base shale drapes and muddy debrite bodies have been identified as having a critical control on channel connectivity and reservoir performance (Li & Caers 2007;Barton et al 2010;Funk et al 2012;Alpak et al 2013), other heterogeneities, particularly towards the channel margins, such as fine-grained low-density turbidite partings, deposits of fluid muds, and partly eroded shales associated with minor abandonment and flooding surfaces are under-represented, or lack detail, in descriptions of outcrop analogues and are poorly imaged in shallow seismic data. The recognition criteria for the origin, diversity and geometry of thin and discontinuous, intra-reservoir shales commonly remains a critical uncertainty in many developments, and even in mature fields (e.g.…”

Section: Evolving Geological Conceptsmentioning

confidence: 99%

Tertiary deep-marine reservoirs of the North Sea region: an introduction

McKie

Rose²,

Hartley

et al. 2015

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Channel trajectories control deep‐water stratigraphic architecture

Morris

Sylvester

Covault

et al. 2022

The Depositional Record

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Interpretation of deep‐water channel deposits is challenging because the spatial arrangement of their constituent lithologies is highly variable. This variability is often thought to be a signature of complex interactions between controlling boundary conditions and processes. A three‐dimensional forward stratigraphic model of a sinuous meandering channel is used to explore the production of channelised deep‐water stratigraphy. This model highlights three stages of stratigraphic evolution for channel belts: (1) an initial phase of rapid growth in mean belt width and variability in belt width driven by increasing channel sinuosity; (2) a subsequent phase of reduced belt‐width growth rate because of cutoff processes; and (3) a mature phase during which repeated bend lifecycles act to produce a statistically stable channel‐belt width. When a trajectory defining the vertical movement of a channel over time is added to the model, commonly recognised patterns of deep‐water channel‐belt stratigraphy are produced. These results demonstrate how forward stratigraphic models provide insights into processes governing the evolution of deep‐water stratigraphy that elude interpretations of static outcrops and seismic images of subsurface examples.

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The impact of fine-scale turbidite channel architecture on deep-water reservoir performance

Cited by 37 publications

References 26 publications

The Stratigraphic Record of Submarine-Channel Evolution

The Stratigraphic Record of Submarine-Channel Evolution

Tertiary deep-marine reservoirs of the North Sea region: an introduction

Channel trajectories control deep‐water stratigraphic architecture

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