A numerical study of the additive Schwarz preconditioned exact Newton method (ASPEN) as a nonlinear preconditioner for immiscible and compositional porous media flow

Klemetsdal, Øystein; Moncorgé, Arthur; Møyner, Olav; Lie, Knut–Andreas

doi:10.1007/s10596-021-10090-x

Cited by 11 publications

(6 citation statements)

References 50 publications

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“…For instance, during dynamic rupture, the fluid state fields exhibit changes that are localized to the vicinity of traveling mechanical waves. This behavior can be exploited to reduce the computational cost; for example, by using adaptive solution methods (e.g., Klemetsdal, Moncorgé, et al., 2021; Sheth & Younis, 2017; Sheth et al., 2020), mesh refinement methods (e.g., Klemetsdal, Møyner, et al., 2021), and sequential coupling between elastodynamic and poroelastic models.…”

Section: Discussionmentioning

confidence: 99%

Automatic Time Step Control to Resolve Hydromechanically Driven Fault Reactivation, Spontaneous Nucleation, and Seismic Arrest

Han,

Ren,

Younis

2023

Water Resources Research

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A physical understanding of the progression from flow‐driven (quasi‐static) poromechanical deformation to dynamic fault rupture is critical to the resilient operations of several engineering systems. These processes are bridged by a progression from fault reactivation to the spontaneous nucleation of unstable sliding. Toward addressing this challenge, novel automatic time step size control methods are developed to enable accurate and efficient simulation of these dynamics and transitions from the first principles. The controllers combine local models for discretization error and Coulomb failure conditions to automatically adjust the time step size across several orders of magnitude. The methods do not require additional empirical or theoretical input and can resolve the pre‐rupture, interseismic, and seismic periods to the allowed accuracy. The computational results reveal that the proposed methods automatically capture the onset of reactivation and nucleation for homogeneous and heterogeneous fields. Hydrodynamic and structural heterogeneity lead to disparate critical nucleation sizes compared to those predicted by theory. The results highlight its potential in predicting induced seismicity in realistic subsurface engineering systems and at practical scales.

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Section: Discussionmentioning

confidence: 99%

Automatic Time Step Control to Resolve Hydromechanically Driven Fault Reactivation, Spontaneous Nucleation, and Seismic Arrest

Han,

Ren,

Younis

2023

Water Resources Research

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“…The multiplicative Schwarz method has been used to split boundary value problems (BVP) into subproblems solver on smaller physical domains [29][30][31][32][33]. It has also been used to split a coupled BVP into subproblems based on the physics [34][35][36], each subproblem being solved on the full domain to update one of the fields (here, pressure and saturation).…”

Section: Field-split Multiplicative Schwarz Newton Methodsmentioning

confidence: 99%

“…Two distinct directions have been explored. A class of nonlinear preconditioners leverages domain decomposition methods [29][30][31][32][33] to precondition the nonlinear system in a computationally inexpensive way and speed up convergence. In this work, we focus on nonlinear preconditioners obtained by splitting the system by physical field [34][35][36].…”

Section: Introductionmentioning

confidence: 99%

Comparison of nonlinear field-split preconditioners for two-phase flow in heterogeneous porous media

Ndiaye¹,

Hamon²

2022

Preprint

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This work focuses on the development of a two-step field-split nonlinear preconditioner to accelerate the convergence of two-phase flow and transport in heterogeneous porous media. We propose a field-split algorithm named Field-Split Multiplicative Schwarz Newton (FSMSN), consisting in two steps: first, we apply a preconditioning step to update pressure and saturations nonlinearly by solving approximately two subproblems in a sequential fashion; then, we apply a global step relying on a Newton update obtained by linearizing the system at the preconditioned state. Using challenging test cases, FSMSN is compared to an existing field-split preconditioner, Multiplicative Schwarz Preconditioned for Inexact Newton (MSPIN), and to standard solution strategies such as the Sequential Fully Implicit (SFI) method or the Fully Implicit Method (FIM). The comparison highlights the impact of the upwinding scheme in the algorithmic performance of the preconditioners and the importance of the dynamic adaptation of the subproblem tolerance in the preconditioning step. Our results demonstrate that the two-step nonlinear preconditioning approachand in particular, FSMSN-results in a faster outer-loop convergence than with the SFI and FIM methods. The impact of the preconditioners on computational performance-i.e., measured by wall-clock time-will be studied in a subsequent publication.

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“…Nonlinear preconditioning appears to be particularly efficient in the application to models of subsurface flow and reactive transport [9], [12], where the failures and lack of robustness of nonlinear solvers is one the major factors limiting the reliability of the simulation codes. In those applications, the major benefit seems to result in the form of an extended convergence region, which, in case of time-dependent problems, allows for larger time steps [12].…”

Section: Introductionmentioning

confidence: 99%

On Global and Monotone Convergence of the Preconditioned Newton’s Method for Some Mildly Nonlinear Systems

Brenner

2024

Lecture Notes in Computational Science and Engineering

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A numerical study of the additive Schwarz preconditioned exact Newton method (ASPEN) as a nonlinear preconditioner for immiscible and compositional porous media flow

Cited by 11 publications

References 50 publications

Automatic Time Step Control to Resolve Hydromechanically Driven Fault Reactivation, Spontaneous Nucleation, and Seismic Arrest

Automatic Time Step Control to Resolve Hydromechanically Driven Fault Reactivation, Spontaneous Nucleation, and Seismic Arrest

Comparison of nonlinear field-split preconditioners for two-phase flow in heterogeneous porous media

On Global and Monotone Convergence of the Preconditioned Newton’s Method for Some Mildly Nonlinear Systems

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