An adaptive stabilized finite element scheme for a water quality model

Araya, Rodolfo; Behrens, Edwin M.; Rodrı́guez, Rodolfo

doi:10.1016/j.cma.2006.07.019

Cited by 9 publications

(17 citation statements)

References 22 publications

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“…The main goal of this article is to develop a posteriori error estimates for elliptic second order partial differential equations on two-and three-dimensional domains with point sources. Elliptic problems with Dirac measure source terms arise in modeling different applications as, for instance, the electric field generated by a point charge, the acoustic monopoles or pollutant transport and degradation in an aquatic media where, due to the different scales involved, the pollution source is modeled as supported on a single point [3]. Other applications involve the coupling between reaction-diffusion problems taking place in domains of different dimension, which arise in tissue perfusion models [11].…”

Section: Introductionmentioning

confidence: 99%

“…A posteriori error estimates on two dimensional domains have been obtained by Araya et al [3,4] for the error measured in L p (1 < p < ∞) and W 1,p (p 0 < p < 2) for certain value of p 0 , and by Gaspoz et al [16] for the error measured in H s (1/2 < s < 1). Recall that the usual test and ansatz space for elliptic problems is the Sobolev space H 1 0 = W 1,2 0 .…”

Section: Introductionmentioning

confidence: 99%

“…Point sources do not belong to the dual space of H 1 0 , because H 1 0 is not immersed into the space of continuous functions, but in two dimensions very little is missing, since functions in W 1,p 0 and H s 0 are continuous if p > 2 and s > 1. This fact was exploited in [3,4] and [16].…”

Section: Introductionmentioning

confidence: 99%

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A posteriorierror estimates for elliptic problems with Dirac measure terms in weighted spaces

2014

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In this article we develop a posteriori error estimates for second order linear elliptic problems with point sources in two-and three-dimensional domains. We prove a global upper bound and a local lower bound for the error measured in a weighted Sobolev space. The weight considered is a (positive) power of the distance to the support of the Dirac delta source term, and belongs to the Muckenhoupt's class A2. The theory hinges on local approximation properties of either Clément or Scott-Zhang interpolation operators, without need of modifications, and makes use of weighted estimates for fractional integrals and maximal functions. Numerical experiments with an adaptive algorithm yield optimal meshes and very good effectivity indices.

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Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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A posteriorierror estimates for elliptic problems with Dirac measure terms in weighted spaces

2014

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“…A.) (Araya and Venegas, 2014;Araya et al, 2007bAraya et al, , 2007a, which solves the steady state heat equation. The model consists of an oceanic slab with constant dip angle, subducting beneath a nondeforming continental plate.…”

Section: Methodsmentioning

confidence: 99%

Depth‐Dependent Geometry of the Liquiñe‐Ofqui Fault Zone and Its Relation to Paths of Slab‐Derived Fluids

Catalán

Bataille

Araya

2017

Geophysical Research Letters

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Using a nonhomogeneous elastic model for the south Chile subduction zone, we calculate the depth-dependent geometry of the Liquiñe-Ofqui Fault Zone (LOFZ), considering that faults develop where shear stress is maximum. Shear stress develops due to the oblique subduction process, depending on shear modulus which varies as a function of the amount of fluids within the overriding plate. Regions with different values of shear modulus are obtained by the geometries of isotherms calculated from a thermal model. Based on the principle that fluids move from higher to lower pressure regions, we calculate paths of fluids from the subducting slab toward the free surface. In the vicinity of the volcanic arc, the obtained fluid paths agree with the geometry of the LOFZ, suggesting that margin-parallel strike-slip faults could serve as pathways for fluids through the overriding plate in oblique subduction zones.

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“…We consider both the case of regular sources, i.e.,

g \in L^{2} (Ω)

, and the case of a singular point source assuming that

g = f + ν δ_{x_{0}}

, where

f \in L^{2} (Ω), ν \in ℝ

and

δ_{x_{0}}

is the Dirac delta distribution supported at an inner point x 0 of Ω. Applications arise in different areas, such as in the study of pollutant diffusion in aquatic media , in the mathematical modeling of electromagnetic fields , or in optimal control of elliptic problems with state constraints . Other applications involve the coupling between reaction‐diffusion problems taking place in domains of different dimension, which arise in tissue perfusion models .…”

Section: Introductionmentioning

confidence: 99%

Adaptive control of local errors for elliptic problems using weighted Sobolev norms

Garau

Morín

2017

Numerical Methods Partial

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We develop an a posteriori error estimator which focuses on the local H 1 error on a region of interest. The estimator bounds a weighted Sobolev norm of the error and is efficient up to oscillation terms. The new idea is very simple and applies to a large class of problems. An adaptive method guided by this estimator is implemented and compared to other local estimators, showing an excellent performance.

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An adaptive stabilized finite element scheme for a water quality model

Cited by 9 publications

References 22 publications

A posteriorierror estimates for elliptic problems with Dirac measure terms in weighted spaces

A posteriorierror estimates for elliptic problems with Dirac measure terms in weighted spaces

Depth‐Dependent Geometry of the Liquiñe‐Ofqui Fault Zone and Its Relation to Paths of Slab‐Derived Fluids

Adaptive control of local errors for elliptic problems using weighted Sobolev norms

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