Artículo
Unconditionally energy stable fully discrete schemes for a chemo-repulsion model
Autor/es | Guillén González, Francisco Manuel
Rodríguez Bellido, María Ángeles Rueda Gómez, Diego Armando |
Departamento | Universidad de Sevilla. Departamento de Ecuaciones Diferenciales y Análisis Numérico |
Fecha de publicación | 2019-09 |
Fecha de depósito | 2019-09-10 |
Publicado en |
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Resumen | This work is devoted to studying unconditionally energy stable
and mass-conservative numerical schemes for the following repulsive-productive chemotaxis model: find u ≥ 0, the cell density, and v ≥ 0, the chemical ... This work is devoted to studying unconditionally energy stable and mass-conservative numerical schemes for the following repulsive-productive chemotaxis model: find u ≥ 0, the cell density, and v ≥ 0, the chemical concentration, such that ∂tu − Δu −∇· (u∇v) = 0 in Ω, t> 0, ∂tv − Δv + v = u in Ω, t> 0, in a bounded domain Ω ⊆ Rd, d = 2, 3. By using a regularization technique, we propose three fully discrete Finite Element (FE) approximations. The first one is a nonlinear approximation in the variables (u, v); the second one is another nonlinear approximation obtained by introducing σ = ∇v as an auxiliary variable; and the third one is a linear approximation constructed by mixing the regularization procedure with the energy quadratization technique, in which other auxiliary variables are introduced. In addition, we study the well-posedness of the numerical schemes, proving unconditional existence of solution, but conditional uniqueness (for the nonlinear schemes). Finally, we compare the behavior of such schemes throughout several numerical simulations and provide some conclusions. |
Identificador del proyecto | MTM2015-69875-P |
Cita | Guillén González, F.M., Rodríguez Bellido, M.Á. y Rueda Gómez, D.A. (2019). Unconditionally energy stable fully discrete schemes for a chemo-repulsion model. Mathematics of Computation, 88 (319), 2069-2099. |
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