Asymptotic Solution for Three-Dimensional Reaction–Diffusion–Advection Equation with Periodic Boundary Conditions

A. Liubavin; M. Ni; Y. Zhang; D. Chaikovskii

doi:10.1134/S0012266124090027

Asymptotic Solution for Three-Dimensional Reaction–Diffusion–Advection Equation with Periodic Boundary Conditions

A. Liubavin^*, M. Ni^*, Y. Zhang^*, D. Chaikovskii^*

^*Corresponding author for this work

School of Mathematics and Statistics

Research output: Contribution to journal › Article › peer-review

Abstract

Abstract: In this study, we investigate the dynamics of moving fronts in three-dimensional spaces,which form as a result of in-situ combustion during oil production. This phenomenon is alsoobserved in other contexts, such as various autowave models and the propagation of acousticwaves. Our analysis involves a singularly perturbed reaction–diffusion–advection typeinitial–boundary value problem of a general form. We employ methods from asymptotic theory todevelop an approximate smooth solution with an internal layer. Using local coordinates, we focuson the transition layer, where the solution undergoes rapid changes. Once the location of thetransition layer is established, we can describe the solution across the full domain of the problem.Numerical examples are provided, demonstrating the high accuracy of the asymptotic method inpredicting the behaviors of moving fronts.

Original language	English
Pages (from-to)	1134-1152
Number of pages	19
Journal	Differential Equations
Volume	60
Issue number	9
DOIs	https://doi.org/10.1134/S0012266124090027
Publication status	Published - Sept 2024

Keywords

moving front
quasilinear reaction–diffusion–advection equation
singular perturbed PDE

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10.1134/S0012266124090027

Cite this

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title = "Asymptotic Solution for Three-Dimensional Reaction–Diffusion–Advection Equation with Periodic Boundary Conditions",

abstract = "Abstract: In this study, we investigate the dynamics of moving fronts in three-dimensional spaces,which form as a result of in-situ combustion during oil production. This phenomenon is alsoobserved in other contexts, such as various autowave models and the propagation of acousticwaves. Our analysis involves a singularly perturbed reaction–diffusion–advection typeinitial–boundary value problem of a general form. We employ methods from asymptotic theory todevelop an approximate smooth solution with an internal layer. Using local coordinates, we focuson the transition layer, where the solution undergoes rapid changes. Once the location of thetransition layer is established, we can describe the solution across the full domain of the problem.Numerical examples are provided, demonstrating the high accuracy of the asymptotic method inpredicting the behaviors of moving fronts.",

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author = "A. Liubavin and M. Ni and Y. Zhang and D. Chaikovskii",

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T1 - Asymptotic Solution for Three-Dimensional Reaction–Diffusion–Advection Equation with Periodic Boundary Conditions

AU - Liubavin, A.

AU - Ni, M.

AU - Zhang, Y.

AU - Chaikovskii, D.

N1 - Publisher Copyright: © Pleiades Publishing, Ltd. 2024.

PY - 2024/9

Y1 - 2024/9

N2 - Abstract: In this study, we investigate the dynamics of moving fronts in three-dimensional spaces,which form as a result of in-situ combustion during oil production. This phenomenon is alsoobserved in other contexts, such as various autowave models and the propagation of acousticwaves. Our analysis involves a singularly perturbed reaction–diffusion–advection typeinitial–boundary value problem of a general form. We employ methods from asymptotic theory todevelop an approximate smooth solution with an internal layer. Using local coordinates, we focuson the transition layer, where the solution undergoes rapid changes. Once the location of thetransition layer is established, we can describe the solution across the full domain of the problem.Numerical examples are provided, demonstrating the high accuracy of the asymptotic method inpredicting the behaviors of moving fronts.

AB - Abstract: In this study, we investigate the dynamics of moving fronts in three-dimensional spaces,which form as a result of in-situ combustion during oil production. This phenomenon is alsoobserved in other contexts, such as various autowave models and the propagation of acousticwaves. Our analysis involves a singularly perturbed reaction–diffusion–advection typeinitial–boundary value problem of a general form. We employ methods from asymptotic theory todevelop an approximate smooth solution with an internal layer. Using local coordinates, we focuson the transition layer, where the solution undergoes rapid changes. Once the location of thetransition layer is established, we can describe the solution across the full domain of the problem.Numerical examples are provided, demonstrating the high accuracy of the asymptotic method inpredicting the behaviors of moving fronts.

KW - moving front

KW - quasilinear reaction–diffusion–advection equation

KW - singular perturbed PDE

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U2 - 10.1134/S0012266124090027

DO - 10.1134/S0012266124090027

M3 - Article

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SN - 0012-2661

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EP - 1152

JO - Differential Equations

JF - Differential Equations

IS - 9

ER -

Asymptotic Solution for Three-Dimensional Reaction–Diffusion–Advection Equation with Periodic Boundary Conditions

Abstract

Keywords

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