3-D mechanical analysis of complex reservoirs: a novel mesh-free approach

Wees, Jan-Diederik van; Pluymaekers, Maarten; Osinga, S.; Fokker, P.A.; Thienen-Visser, K. van; Orlić, B.; Wassing, B.B.T.; Hegen, Dries; Candela, Thibault

doi:10.1093/gji/ggz352

Cited by 19 publications

(15 citation statements)

References 54 publications

(71 reference statements)

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“…As shown in a number of previous studies (e.g. Buijze, van den Bogert et al, 2019;Buijze et al, 2017;Haug et al, 2018;Mulders, 2003;van Wees et al, 2019;Zbinden et al, 2017), depletion of offset reservoir compartments results in normal and shear stress concentrations developing at the top of the hanging wall and at the base of the footwall (Figure 3-9a and b), while shear stress minima develop at the top of the footwall and base of the hanging wall (Figure 3-9b). The net result of these stress changes is that maxima in SCU (Equation 3-22) appear at the top of the hanging wall and at the base of the footwall, resulting in fault reactivation at these two locations after 7 MPa of depletion (Figure 3-9d).…”

Section: 2 Stress Changes and Fault Reactivation Due To Compactiomentioning

confidence: 52%

“…Many modeling studies have assumed linear elastic material properties to model the stresses induced by depletion of the Groningen field as well as the response of other fields to a variety of subsurface activities (Buijze, van den Bogert et al, 2019;Haug et al, 2018;Mulders, 2003;Nagelhout & Roest, 1997;Roest & Kuilman, 1994;Segall, 1989;Segall et al, 1994;van Wees et al, 2019, Zbinden et al, 2017. The stressstrain response resulting from the present elastoplasic MCC model was near-linear in the stress range of interest.…”

Section: 5 Approximation Of MCC Behavior With Apparent Linear Elamentioning

confidence: 98%

“…The effect of the decrease in stress path parameter on seismicity may thus be masked by ongoing compaction. It would be an interesting avenue for future studies to evaluate the effect of stress path changes on fault reactivation in a field-scale model with multiple faults -such as the geomechanical reservoir simulator MACRIS (Candela, Thibault et al, 2019;van Wees et al, 2019).…”

Section: 6 Implications For Fault Reactivation and Induced Seismimentioning

confidence: 99%

“…Sensitivity to the nucleation process could be investigated by comparing against the model realizations in this study. The analysis could even be extended to 3D, by using recent 3D fast models for the computation of stress changes in faulted, geometrically complex reservoirs (van Wees et al, 2019), and/or analytical solutions for elongated, along-strike rupture propagation for ruptures confined along the fault dip (Weng & Ampuero, 2019). The current study forms a first step in understanding the alongdip behavior of production-induced rupture, considering stresses and friction that are heterogeneous along the fault dip.…”

Section: Comparison With Seismological Observations From the Gronimentioning

confidence: 99%

“…Geomechanical modeling indicates that these events are likely induced by (a combination of) production-related poroelastic stress changes, stress changes caused by gradients in compaction of the sandstone reservoir where the depleting reservoir compartments are offset by faults (i.e. differential compaction), stress changes due to salt caprock creep (where salt caprock is present), and by delayed pore pressure diffusion from faults into the depleting reservoir (Buijze, van den Bogert et al, 2019;Haug et al, 2018;Mulders, 2003;Nagelhout & Roest, 1997;Roest & Kuilman, 1994;Segall, P., 1989;Segall, P. et al, 1994;van Wees et al, 2019;Zbinden et al, 2017). The relationship between pressure decrease, reservoir compaction, fault stressing and thus-forced fault reactivation is one of the key ingredients for understanding the spatiotemporal behavior of seismicity and assessing the potential size of the induced events.…”

Section: Introductionmentioning

confidence: 99%

See 4 more Smart Citations

Numerical and experimental simulation of fault reactivation and earthquake rupture applied to induced seismicity in the Groningen gas field

Buijze¹

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Section: 2 Stress Changes and Fault Reactivation Due To Compactiomentioning

confidence: 52%

Section: 5 Approximation Of MCC Behavior With Apparent Linear Elamentioning

confidence: 98%

Section: 6 Implications For Fault Reactivation and Induced Seismimentioning

confidence: 99%

Section: Comparison With Seismological Observations From the Gronimentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

See 3 more Smart Citations

Numerical and experimental simulation of fault reactivation and earthquake rupture applied to induced seismicity in the Groningen gas field

Buijze¹

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The effect of Biot coefficient and elastic moduli stress–pore pressure dependency on poroelastic response to fluid injection: laboratory experiments and geomechanical modeling

2020

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Biot coefficient and elastic moduli are typically assumed to have a constant value for analyzing poroelastic effects of fluid injection. To investigate the stress-pore pressure dependency of Biot coefficient and elastic moduli, we conducted a series of laboratory experiments on a porous dolomite core sample from a reef in Michigan basin. We varied the confining stress as well as the pore pressure in the experiments. Then, modeling was performed using analytical poroelastic solutions and a coupled two-phase flow-geomechanical numerical simulation (for CO 2 injection). The modeling results show that the variability of Biot coefficient and elastic moduli should be included in the geomechanical modeling to accurately predict the poroelastic responses of injection (i.e., stress changes and surface uplift). Using a constant stress-independent Biot coefficient elastic moduli, which is the assumption in poroelastic modeling, leads to underestimation of the stress change and surface uplift due to injection compared to a realistic stress-pore pressure dependent Biot coefficient, which is updated at each time step of injection modeling. Modeling results indicate that decreasing elastic modulus combined with Biot coefficient increase due to the fluid injection could lead to a larger surface uplift and stress changes in the reservoir. In addition, the stress changes and uplift due to injection are a function of initial in situ stress due to Biot coefficient and elastic modulus stress-pore pressure dependency.

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Steady-State Flow Through a Subsurface Reservoir with a Displaced Fault and its Poro-elastic Effects on Fault Stresses

Cornelissen,

Jansen

2023

Transp Porous Med

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We consider steady-state single-phase confined flow through a subsurface porous layer containing a displaced, fully conductive fault causing a sudden jump in the flow path, and we employ (semi-)analytical techniques to compute the corresponding pressures and fault stresses. In particular, we obtain a new solution for the pressure field with the aid of conformal mapping and a Schwarz–Christoffel transformation. Moreover, we use an existing technique to compute the poro-elastic stress field with the aid of inclusion theory. The additional resistance to fluid flow provided by a displaced fault, relative to the resistance in a layer without a fault, is a function of dip angle, fault throw divided by reservoir height, and reservoir width divided by reservoir height. Fluid flow has a larger effect on fault stresses in case of injection than in case of depletion, where injection with up-dip flow results in increased zones of fault slip near the bottom of the reservoir. Opposedly, injection with down-dip flow results in increased slip near the top of the reservoir. An order-of-magnitude estimate of the effect of steady-state flow across displaced faults in the Groningen natural gas reservoir shows that the effect on fault stresses is probably negligible. A similar estimate of the effect in low-enthalpy geothermal doublets indicates that steady-state flow may possibly play a small role, in particular close to the injector, but site-specific assessments will be necessary to quantify the effect.

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3-D mechanical analysis of complex reservoirs: a novel mesh-free approach

Cited by 19 publications

References 54 publications

Numerical and experimental simulation of fault reactivation and earthquake rupture applied to induced seismicity in the Groningen gas field

Numerical and experimental simulation of fault reactivation and earthquake rupture applied to induced seismicity in the Groningen gas field

The effect of Biot coefficient and elastic moduli stress–pore pressure dependency on poroelastic response to fluid injection: laboratory experiments and geomechanical modeling

Steady-State Flow Through a Subsurface Reservoir with a Displaced Fault and its Poro-elastic Effects on Fault Stresses

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