Integrated charge and seal assessment in the Monagas fold and thrust belt of Venezuela

Neumaier, Martin; Littke, Ralf; Hantschel, Thomas; Maerten, Laurent; Joonnekindt, J.P.; Kukla, Peter A.

doi:10.1306/01131412157

Cited by 23 publications

(13 citation statements)

References 37 publications

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“…Modern software programs of basin modeling allow simultaneously studying a number of processes from sedimentation and immersion to kerogen maturation and multiphase fluid flow [4][5][6][7][8][9][10][11][12][13][14][15][16]. Today there is a fairly large number of basin modeling software programs.…”

Section: Methodsmentioning

confidence: 99%

Features of geological structure and formation of oil & gas deposits in the Vuktyl thrust fault region

Kuznetsova¹,

Карасева²

2017

Вестник ПНИПУ. Геология. Нефтегазовое и горное дело

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Section: Methodsmentioning

confidence: 99%

Features of geological structure and formation of oil & gas deposits in the Vuktyl thrust fault region

Kuznetsova¹,

Карасева²

2017

Вестник ПНИПУ. Геология. Нефтегазовое и горное дело

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“…Typically, 2D basin and petroleum system models use an event‐stepping method where sediments undergo layer‐by‐layer backstripping to determine an estimated initial thickness and basin geometry for subsequent use in forward modelling (Hantschel & Kauerauf, ). In regions where there have been significant horizontal offset of layers on faults, however, the event‐stepping method leads to incorrect modelling of palaeo‐geometry (Neumaier et al ., ). Additionally, event‐stepping models cannot be used in thrust‐faulted environments where a single horizon is duplicated along the z ‐axis of the model grid due to computational limitations.…”

Section: Modellingmentioning

confidence: 97%

“…To avoid these problems, a palaeo‐stepping model was used for this study. Palaeo‐stepping models require the user to specify basin geometry though time (Hantschel & Kauerauf, ), and are the only type of model that can handle complex thrusting geometries (e.g., Gusterhuber et al ., ; Neumaier et al ., ). In this case, the horizon and fault geometries reconstructed in Dynel 2D® were used as direct input for palaeo‐basin geometries for each time step.…”

Section: Modellingmentioning

confidence: 97%

Basin and petroleum system modelling of the East Coast Basin, New Zealand: a test of overpressure scenarios in a convergent margin

2015

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In the East Coast Basin (ECB), an active convergent margin of the North Island, New Zealand, the smectite-rich Eocene Wanstead Formation forms an effective regional seal, creating high overpressure in the underlying Cretaceous through Palaeocene units due to disequilibrium compaction. This study examines the evolution of pore pressure and porosity in Hawke Bay of the ECB based on stepwise structural reconstruction of a stratigraphic and structural framework derived from interpretation of a regional two-dimensional seismic line. This framework is incorporated into a basin and petroleum system model to predict the generation, distribution, and dissipation of overpressure, and examine the influence of faults, erosion, structural thickening, and seal effectiveness of the Wanstead Formation on pore pressure evolution. We find that natural hydraulic fracturing is likely occurring in sub-Wanstead source rocks, which makes it a favourable setting for potential shale gas plays. We use poroelastic modelling to investigate the impact of horizontal bulk shortening due to tectonic compression on pore pressure and the relative order of principal stresses. We find that shortening modestly increases pore pressure. When 5% or greater shortening occurs, the horizontal stress may approach and exceed vertical stress in the last 4 Myr of the basin's history. Shortening impacts both the magnitude and relative order of principal stresses through geological time. Due to the overpressured nature of the basin, we suggest that subtle changes in stress regime are responsible for the significant changes in structural deformational styles observed, enabling compressional, extensional, and strike-slip fault regimes to all occur during the tectonic history and, at times, simultaneously.

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“…Because accuracy is crucial, several techniques are commonly used in combination to reduce uncertainty in predictions. Two main approaches are used for pore pressure prediction: (1) porosity-based methods which depend on rock property relationships and the analysis of the trends with depth (Van Ruth et al., 2002;Yang and Aplin, 2004;Bera, 2010;Zhang, 2011) and (2) forward basin modelling (Schneider et al, 1996;Bekele et al, 2001;Schneider and Hay, 2001;Bolås et al, 2004;Allwardt et al, 2009;Hantschel and Kauerauf, 2009;Neumaier et al, 2014), which provides numerical simulations of different physical and chemical mechanisms of overpressure generation and dissipation during basin evolution and therefore is capable of capturing pore pressure history over geologic times. The main limitation of both approaches is that the adopted mechanical compaction models are unidimensional and based on the vertical effective stress.…”

Section: Introductionmentioning

confidence: 99%

Assessing the implications of tectonic compaction on pore pressure using a coupled geomechanical approach

Obradors-Prats

Rouainia

Aplin

et al. 2017

Marine and Petroleum Geology

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Use policyThe full-text may be used and/or reproduced, and given to third parties in any format or medium, without prior permission or charge, for personal research or study, educational, or not-for-prot purposes provided that:• a full bibliographic reference is made to the original source • a link is made to the metadata record in DRO • the full-text is not changed in any way The full-text must not be sold in any format or medium without the formal permission of the copyright holders.Please consult the full DRO policy for further details. AbstractOverpressure prediction in tectonic environments is a challenging topic. The available pore pressure prediction methods are designed to work in environments where compaction is mostly one dimensional and driven by the vertical effective stress applied by the overburden. Furthermore, the impact of tectonic deformation on stresses, porosity and overpressure is still poorly understood. We use a novel methodology to capture the true compaction phenomena occurring in an evolving 3D stress regime by integrating a fully-coupled geomechanical approach with a critical state constitutive model. To this end, numerical models consisting of 2D plane strain clay columns are developed to account for compaction and overpressure generation during sedimentation and tectonic activity. We demonstrate that a high deviatoric stress is generated in compressional tectonic basins, resulting in a substantial decrease in porosity with continuing overpressure increase.The overpressure predictions from our numerical models are then compared to those estimated by the equivalent depth method (EDM) in order to quantify the error induced when using classical approaches, based on vertical effective stress, in tectonic environments. The stress paths presented here reveal that a deviation from the uniaxial burial trend can substantially reduce the accuracy of the EDM overpressure predictions.

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Integrated charge and seal assessment in the Monagas fold and thrust belt of Venezuela

Cited by 23 publications

References 37 publications

Features of geological structure and formation of oil & gas deposits in the Vuktyl thrust fault region

Features of geological structure and formation of oil & gas deposits in the Vuktyl thrust fault region

Basin and petroleum system modelling of the East Coast Basin, New Zealand: a test of overpressure scenarios in a convergent margin

Assessing the implications of tectonic compaction on pore pressure using a coupled geomechanical approach

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