A Cartesian Grid Embedded Boundary Method for the Heat Equation on Irregular Domains

McCorquodale, Peter; Colella, P.; Johansen, Hans

doi:10.1006/jcph.2001.6900

Cited by 140 publications

(139 citation statements)

References 6 publications

(14 reference statements)

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“…However, Crank-Nicolson is only neutrally stable, and we found that it led to weak instabilities at coarse-fine interfaces, given the other choices we made in this algorithm. This behavior was similar to that noted at embedded boundaries in [16,20]. To eliminate this problem, we found it necessary to employ a different approach to computing the viscous terms in (1), using the L 0 scheme described in [30].…”

Section: Single-level Time Discretizationsupporting

confidence: 68%

“…Previous semi-implicit methods have used the Crank-Nicolson scheme to compute the viscous terms in the update. However, for the discretizations used in this work, we found the neutrallystable Crank-Nicolson scheme suffered from weak instabilities at coarsefine interfaces, similar to the behavior noticed at embedded boundaries in [16,20]. To eliminate this problem, we employ a second-order semi-implicit Runge-Kutta scheme based on the L 0 -stable scheme in [30].…”

Section: Introductionmentioning

confidence: 56%

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A cell-centered adaptive projection method for the incompressible Navier–Stokes equations in three dimensions

Martín

Colella

Graves

2008

Journal of Computational Physics

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We present a method for computing incompressible viscous flows in three dimensions using block-structured local refinement in both space and time. This method uses a projection formulation based on a cell-centered approximate projection, combined with the systematic use of multilevel elliptic solvers to compute increments in the solution generated at boundaries between refinement levels due to refinement in time. We use an L 0 -stable second-order semi-implicit scheme to evaluate the viscous terms. Results are presented to demonstrate the accuracy and effectiveness of this approach.

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Section: Single-level Time Discretizationsupporting

confidence: 68%

Section: Introductionmentioning

confidence: 56%

A cell-centered adaptive projection method for the incompressible Navier–Stokes equations in three dimensions

Martín

Colella

Graves

2008

Journal of Computational Physics

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“…The original boundary and the approximated one lie in the same R d−1 space. For example, the following methods can be found in this group: truncated domains methods [6,7], immersed interface methods (I.I.M.) [8,9], penalty methods [1,2,10,11,12,4], fictitious domain methods with Lagrange multipliers [13,14,15], an adapted Galerkin method proposed in [16], and recent work on a fictitious model with flux and solutions jumps for general embedded boundary conditions [17,18].…”

Section: Introductionmentioning

confidence: 99%

“…[1,2,8,10,15,6,24] and the references herein. Only a few studies have been devoted to embedded Fourier B.C.…”

Section: Introductionmentioning

confidence: 99%

A fictitious domain approach with spread interface for elliptic problems with general boundary conditions

Ramière

Angot

Belliard

2007

Computer Methods in Applied Mechanics and Engineering

129

109

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“…Cartesian grid embedded boundary methods introduced in [21] and [32] to increase the geometric flexibility of finite volume methods. Away from the boundaries of the computational domain, this approach uses traditional finite difference discretizations on a regular Cartesian grid.…”

Section: Survey Of Numerical Algorithmsmentioning

confidence: 99%

Solving partial differential equations on irregular domains with moving interfaces, with applications to superconformal electrodeposition in semiconductor manufacturing

Sethian¹,

Shan²

2008

Journal of Computational Physics

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We present a numerical algorithm for solving partial differential equations on irregular domains with moving interfaces. Instead of the typical approach of solving in a larger rectangular domain, our approach performs most calculations only in the desired domain. To do so efficiently, we have developed a one-sided multigrid method to solve the corresponding large sparse linear systems.Our focus is on the simulation of the electrodeposition process in semiconductor manufacturing in both two and three dimensions. Our goal is to track the position of the interface between the metal and the electrolyte as the features are filled and to determine which initial configurations and physical parameters lead to superfilling.We begin by motivating the set of equations which model the electrodeposition process. Building on existing models for superconformal electrodeposition, we develop a model which naturally arises from a conservation law form of surface additive evolution. We then introduce several numerical algorithms, including a conservative material transport level set method and our multigrid method for one-sided diffusion equations. We then analyze the accuracy of our numerical methods. Finally, we compare our result with experiment over a wide range of physical parameters.

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A Cartesian Grid Embedded Boundary Method for the Heat Equation on Irregular Domains

Cited by 140 publications

References 6 publications

A cell-centered adaptive projection method for the incompressible Navier–Stokes equations in three dimensions

A cell-centered adaptive projection method for the incompressible Navier–Stokes equations in three dimensions

A fictitious domain approach with spread interface for elliptic problems with general boundary conditions

Solving partial differential equations on irregular domains with moving interfaces, with applications to superconformal electrodeposition in semiconductor manufacturing

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