Decoupled Energy Stable Schemes for Phase-Field Models of Two-Phase Complex Fluids

Shen, Jie; Yang, Xiaofeng

doi:10.1137/130921593

Cited by 108 publications

(60 citation statements)

References 45 publications

(67 reference statements)

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“…(3.9). The introduction of an explicit velocity u n * in (3.28) follows a similar approach used in Minjeaud [25] (see also Shen and Yang [37]). Comparing to the replacement of ũ n+1 with u n , the replacement of ũ n+1 with u n * in Eq.…”

Section: A Linear and Decoupled Energy Stable Schemementioning

confidence: 99%

“…A particular advantage of the phase-field approach is that the derived models are usually well-posed nonlinear partial differential equations that satisfy thermodynamics-consistent energy dissipation laws, which makes it possible to carry out mathematical analysis and further design numerical schemes which satisfy corresponding discrete energy dissipation laws. Thus phase field models recently have been the subject of many theoretical and numerical investigations (cf., for instance, [5,8,[12][13][14]19,21,24,31,33,[35][36][37][38]43]). …”

Section: Introductionmentioning

confidence: 99%

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Efficient energy stable numerical schemes for a phase field moving contact line model

Shen

Yang²,

Yu³

2015

Journal of Computational Physics

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111

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In this paper, we present two efficient energy stable schemes to solve a phase field model incorporating moving contact line. The model is a coupled system that consists of incompressible Navier-Stokes equations with a generalized Navier boundary condition and Cahn-Hilliard equation in conserved form. In both schemes the projection method is used to deal with the Navier-Stokes equations and stabilization approach is used for the non-convex Ginzburg-Landau bulk potential. By some subtle explicit-implicit treatments, we obtain a linear coupled energy stable scheme for systems with dynamic contact line conditions and a linear decoupled energy stable scheme for systems with static contact line conditions. An efficient spectral-Galerkin spatial discretization method is implemented to verify the accuracy and efficiency of proposed schemes. Numerical results show that the proposed schemes are very efficient and accurate.

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Section: A Linear and Decoupled Energy Stable Schemementioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Efficient energy stable numerical schemes for a phase field moving contact line model

Shen

Yang²,

Yu³

2015

Journal of Computational Physics

Self Cite

111

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“…In this work, we study a modification of the model presented in where we take into account the anchoring effects and an arbitrary interpolation function can be considered to localize the nematic region (in practice, we consider a fifth‐order polynomial). We derive new linear splitting schemes for nematic–isotropic mixtures, taking into account viscous, mixing, nematic, and anchoring effects, which allows us to split the computation of the three pairs of unknowns ( v , p ) (velocity–pressure), ( c , μ ) (phase field–chemical potential), and ( d , w )(director vector–equilibrium) in three different steps.…”

Section: Introductionmentioning

confidence: 99%

Linear unconditional energy‐stable splitting schemes for a phase‐field model for nematic–isotropic flows with anchoring effects

Guillén-González

Rodríguez-Bellido

Tierra

2016

Numerical Meth Engineering

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Two-phase flows composed of fluids exhibiting different microscopic structure are an important class of engineering materials. The dynamics of these flows are determined by the coupling among three different length scales: microscopic inside each component, mesoscopic interfacial morphology and macroscopic hydrodynamics. Moreover, in the case of complex fluids composed by the mixture between isotropic (newtonian fluid) and nematic (liquid crystal) flows, its interfaces exhibit novel dynamics due to anchoring effects of the liquid crystal molecules on the interface.Firstly, we have introduced a new differential problem to model Nematic-Isotropic mixtures, taking into account viscous, mixing, nematic and anchoring effects and reformulating the corresponding stress tensors in order to derive a dissipative energy law. Then, we provide two new linear unconditionally energy-stable splitting schemes. Moreover, we present several numerical simulations in order to show the efficiency of the proposed numerical schemes and the influence of the different types of anchoring effects in the dynamics of the system.

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“…The techniques developed in this paper can be used to construct efficient numerical schemes in other situations. For example, we have recently extended the approach in this paper to a phase-field model for two-phase complex fluids with matching density [35].…”

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confidence: 99%

Decoupled, Energy Stable Schemes for Phase-Field Models of Two-Phase Incompressible Flows

Shen¹,

Yang²

2015

SIAM J. Numer. Anal.

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230

170

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In this paper we construct two classes, based on stabilization and convex splitting, of decoupled, unconditionally energy stable schemes for Cahn-Hilliard phase-field models of two-phase incompressible flows. At each time step, these schemes require solving only a sequence of elliptic equations, including a pressure Poisson equation. Furthermore, all of these elliptic equations are linear for the schemes based on stabilization, making them the first, to the best of the authors' knowledge, totally decoupled, linear, unconditionally energy stable schemes for phase-field models of two-phase incompressible flows. Thus, the schemes constructed in this paper are very efficient and easy to implement. Introduction.The phase-field approach, whose origin can be traced back to [29] and [38], has been used extensively with much successes and has become one of the major tools to study a variety of interfacial phenomena (cf. [15,3,25,17,22,43], the recent review papers [30,19], and the references therein). A particular advantage of the phase-field approach is that the governing system can be derived from an energy-based variational formalism. This usually leads to thermodynamically consistent energy dissipation laws, which allow us to establish the well posedness (at least local in time) for the coupled nonlinear system.A main challenge in the numerical approximation of phase-field models is how to construct efficient and easy-to-implement numerical schemes which verify a discrete energy law. It has been observed that numerical schemes which do not respect the energy dissipation laws may be "overloaded" with an excessive amount of numerical dissipation near singularities, which in turn lead to large numerical errors, particularly for long time integration [41,10,37,39,6]. Hence, to accurately simulate the dynamic coarse-graining (macroscopic) processes described by the Allen-Cahn and Cahn-Hilliard equations in typical phase-field models that undergo rapid changes at the interface, it is especially desirable to design numerical schemes that preserve the energy dissipation law at the discrete level. Another main advantage of energy stable schemes is that they can be easily combined with an adaptive time stepping strategy. While it is relatively easy to design energy stable schemes which involve solving coupled nonlinear systems at each time step, it is extremely difficult to construct energy schemes that only involve solving decoupled, and preferably linear, elliptic equations. The main difficulties in constructing such schemes include (i) the coupling between

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Decoupled Energy Stable Schemes for Phase-Field Models of Two-Phase Complex Fluids

Cited by 108 publications

References 45 publications

Efficient energy stable numerical schemes for a phase field moving contact line model

Efficient energy stable numerical schemes for a phase field moving contact line model

Linear unconditional energy‐stable splitting schemes for a phase‐field model for nematic–isotropic flows with anchoring effects

Decoupled, Energy Stable Schemes for Phase-Field Models of Two-Phase Incompressible Flows

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