Numerical simulations of bouncing jets

Bonito, Andrea; Guermond, Jean‐Luc; Lee, Sanghyun

doi:10.1002/fld.4071

Cited by 25 publications

(18 citation statements)

References 35 publications

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“…The level set method typically refers to the transport of a smooth distance function whose zero isosurface is the interface to be tracked. The method has been used successfully in many fluid flow applications, see e.g., Sussman et al [38], Osher and Sethian [34], Gibou et al [13], Ville et al [40], Bonito et al [2], but it can also be used in other contexts like shape optimization as in Dapogny et al [10], Yamada et al [43].…”

Section: Numerical Front Tracking and The Level Set Methodsmentioning

confidence: 99%

An conservative anti-diffusion technique for the level set method

Guermond

Luna

Thompson

2017

Journal of Computational and Applied Mathematics

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A novel conservative level set method is introduced for the approximation of two-phase incompressible fluid flows. The method builds on recent conservative level set approaches and utilizes an entropy production to construct a balanced artificial diffusion and artificial anti-diffusion. The method is selftuning, maximum principle preserving, suitable for unstructured meshes, and neither re-initialization of the level set function nor reconstruction of the interface is needed for long-time simulation. Computational results in one, two and three dimensions are presented for finite element and finite volume implementations of the method.

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Section: Numerical Front Tracking and The Level Set Methodsmentioning

confidence: 99%

An conservative anti-diffusion technique for the level set method

Guermond

Luna

Thompson

2017

Journal of Computational and Applied Mathematics

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“…Here the method is inspired by a recent idea proposed in [46] by introducing an (explicit) level-set function ϕ LS for the fracture. However, we also note that employing a level-set function to compute the normal vectors of iso-surfaces has been used for many different applications (for example, see [22,6] and references cited therein). The initial step follows a standard procedure in level-set methods.…”

Section: The Fracture Width Computation Using a Level-set Approachmentioning

confidence: 99%

Iterative coupling of flow, geomechanics and adaptive phase-field fracture including level-set crack width approaches

Lee¹,

Wheeler²,

Wick³

2017

Journal of Computational and Applied Mathematics

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In this work, we present numerical studies of fixed-stress iterative coupling for solving flow and geomechanics with propagating fractures in a porous medium. Specifically, fracture propagations are described by employing a phasefield approach. The extension to fixed-stress splitting to propagating phase-field fractures and systematic investigation of its properties are important enhancements to existing studies. Moreover, we provide an accurate computation of the fracture opening using level-set approaches and a subsequent finite element interpolation of the width. The latter enters as fracture permeability into the pressure diffraction problem which is crucial for fluid filled fractures. Our developments are substantiated with several numerical tests that include comparisons of computational cost for iterative coupling and nonlinear and linear iterations as well as convergence studies in space and time.

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“…Here µ Stab|T denotes the piecewise-constant field of the entropy residual-based viscosity, which can be implemented implicitly or explicitly. More details are found in [295,251,174,296]. We note also that the EG method employs DG variational formulations, but with fewer degrees of freedom.…”

Section: Proppant-enhanced Hydraulic Fracture Propagationmentioning

confidence: 99%

Analytical and variational numerical methods for unstable miscible displacement flows in porous media

Scovazzi

Wheeler

Mikelić

et al. 2017

Journal of Computational Physics

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International audienceThe miscible displacement of one fluid by another in a porous medium has received considerable attention in sub-surface, environmental and petroleum engineering applications. When a fluid of higher mobility displaces another of lower mobility, unstable patterns-referred to as viscous fingering-may arise. Their physical and mathematical study has been the object of numerous investigations over the past century. The objective of this paper is to present a review of these contributions with particular emphasis on variational methods. These algorithms are tailored to real field applications thanks to their advanced features: handling of general complex geometries, robustness in the presence of rough tensor coefficients, low sensitivity to mesh orientation in advection dominated scenarios, and provable convergence with fully unstructured grids. This paper is dedicated to the memory of Dr. Jim Douglas Jr., for his seminal contributions to miscible displacement and variational numerical methods

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Numerical simulations of bouncing jets

Cited by 25 publications

References 35 publications

An conservative anti-diffusion technique for the level set method

An conservative anti-diffusion technique for the level set method

Iterative coupling of flow, geomechanics and adaptive phase-field fracture including level-set crack width approaches

Analytical and variational numerical methods for unstable miscible displacement flows in porous media

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