Overpressure development in sedimentary basins induced by chemo-mechanical compaction of sandstones

Brüch, A.; Guy, Nicolas; Maghous, Samir

doi:10.1016/j.marpetgeo.2019.03.025

Cited by 4 publications

(8 citation statements)

References 71 publications

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“…This section presents the porous material behavior currently implemented in the basin simulator described in Brüch et al 20 The main differences of the constitutive model with respect to its previous version 21 are presented in Sections 2.2 and 2.3. They mainly consist in introducing non-associated formulations for the plastic and viscoplastic models which aim to give more realistic dilating behavior for the sediment material.…”

Section: Constitutive Modelmentioning

confidence: 99%

Coupled poro‐mechanical tangent formulation applied to sedimentary basin modeling

Brüch

Guy

Lemos

et al. 2021

Num Anal Meth Geomechanics

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Sedimentary basin modeling involves large space domains and time periods.Reproducing the compaction processes of the sediment material requires the constitutive model to be formulated in the framework of large irreversible strains, taking both geometric and physical nonlinearities into account. This work presents a tangent formulation for the coupled poro-mechanical system of equations resulting from the weak form of the momentum and fluid mass balance equations. The proposed workflow is integrated in a thermo-poro-mechanical finite element basin simulator. At material level, purely mechanical and chemomechanical deformations are respectively addressed by means of plastic and viscoplastic components in the macroscopic state equations. The accuracy and efficiency of the proposed tangent formulation are assessed through the simulation of a basin geological scenario involving gravitational compaction and tectonic shortening. Both drained and undrained behaviors of the basin rocks are simulated. The procedure has significantly improved the convergence rate and reduced the computational cost with comparison to the original formulation based on the standard poro-elastic coefficients. In order to illustrate the potential of the basin simulator to deal with real case applications, a well model from the Neuquén basin in Argentina is also presented. The results are validated against available numerical and field data for porosity, pore-pressure and temperature.

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Section: Constitutive Modelmentioning

confidence: 99%

Coupled poro‐mechanical tangent formulation applied to sedimentary basin modeling

Brüch

Guy

Lemos

et al. 2021

Num Anal Meth Geomechanics

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“…The role of pore pressure and geothermal gradient has been assessed through numerical formulations in previous works. 9,41,44,51,52 The sedimentary basin undergoing compaction is modeled as an infinite layer, perpendicular to the e 3 direction and lying on a rigid substratum along the plane x 3 = 0. Neglecting the tectonic activity, the gravitational field g = −ge 3 stands for the only external loading in the compaction process.…”

Section: Statement Of the Problemmentioning

confidence: 99%

“…In order to formulate semianalytical solutions for the compaction process in sedimentary basins, a simplified setting relying upon the following assumptions is adopted: (a) the whole sedimentation process takes place under oedometric conditions; (b) the sediment constitutive material exhibits homogeneous and isotropic mechanical properties in its reference state, that is, at the time it is deposited at the top of the basin; (c) the hydromechanical coupling is disregarded in the subsequent analysis (i.e., the effect of pore pressure is not considered), which amounts to addressing the particular case of highly permeable sediment material (fully drained conditions); and (d) the mechanical evolution of the basin is analyzed under isothermal condition, disregarding the effect of geothermal gradient on the material properties and deformation. The role of pore pressure and geothermal gradient has been assessed through numerical formulations in previous works 9,41,44,51,52 …”

Section: Statement Of the Problemmentioning

confidence: 99%

“…A formulation based on limit analysis and micromechanics has been originally proposed in Barthélémy et al 42 for p c . This formulation has been recently modified by Brüch et al 52 using a calibration exponent m p :

p_{c} ()(, ϕ) = p_{c 0} {(\frac{\ln ϕ}{\ln ϕ_{0}})}^{m_{p}},

where p c 0 is the initial consolidation pressure for plasticity.…”

Section: Statement Of the Problemmentioning

confidence: 99%

“…As regards the initial consolidation pressure for plasticity, a deliberately high value is adopted for to better visualize the model predictions and thus clearly illustrate each phase of the compaction process described in Section 3. More realistic values of p c 0 could actually be adopted in order to activate plastic deformation at low overburden levels (see, e.g., Brüch et al 52 ). As it will be commented in Section 4.2, the values considered for material properties in the reference state lead to unrealistically overestimating the extent of upper elastic layer.…”

Section: Illustrative Numerical Basin Simulations—comparison With Fe mentioning

confidence: 99%

See 2 more Smart Citations

Formulation of reference solutions for compaction process in sedimentary basins

Lemos

Brüch

Maghous

2020

Num Anal Meth Geomechanics

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This paper is devoted to the development of semianalytical solutions for the deformation induced by gravitational compaction in sedimentary basins. Formulated within the framework of coupled plasticity-viscoplasticity at large strains, the modeling dedicates special emphasis to the effects of material densification associated with large irreversible porosity changes on the stiffness and hardening of the sediment material. At material level, the purely mechanical compaction taking place in the upper layers of the basin is handled in the context of finite elastoplasticity, whereas the viscoplastic component of behavior is intended to address creep-like deformation resulting from chemomechanical that prevails at deeper layers. Semianalytical solutions describing the evolution of mechanical state of the sedimentary basin along both the accretion and postaccretion periods are presented in the simplified oedometric setting. These solutions can be viewed as reference solutions for verification and benchmarks of basin simulators. The proposed approach may reveal suitable for parametric analyses because it requires only standard mathematics-based software for PDE system resolution. The numerical illustrations provide a quantitative comparison between the derived solutions and finite element predictions from an appropriate basin simulator, thus showing the ability of the approach to accurately capture essential features of basin deformation.

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Coupling 3D geomechanics to classical sedimentary basin modeling: From gravitational compaction to tectonics

Brüch

Colombo

Frey

et al. 2021

Geomechanics for Energy and the Environment

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Overpressure development in sedimentary basins induced by chemo-mechanical compaction of sandstones

Cited by 4 publications

References 71 publications

Coupled poro‐mechanical tangent formulation applied to sedimentary basin modeling

Coupled poro‐mechanical tangent formulation applied to sedimentary basin modeling

Formulation of reference solutions for compaction process in sedimentary basins

Coupling 3D geomechanics to classical sedimentary basin modeling: From gravitational compaction to tectonics

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