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dc.contributor.authorGatica, Gabriel N.-
dc.contributor.authorOyarzúa, Ricardo-
dc.contributor.authorRuiz-Baierd, Ricardo-
dc.contributor.authorSobral, Yuri Dumaresq-
dc.date.accessioned2021-05-19T14:30:42Z-
dc.date.available2021-05-19T14:30:42Z-
dc.date.issued2021-
dc.identifier.citationGATICA, Gabriel N. et al. Banach spaces-based analysis of a fully-mixed finite element method for the steady-state model of fluidized beds. Computers & Mathematics with Applications, v. 84, p. 244-276,15 fev 2021. DOI: https://doi.org/10.1016/j.camwa.2021.01.001.pt_BR
dc.identifier.urihttps://repositorio.unb.br/handle/10482/40942-
dc.language.isoInglêspt_BR
dc.publisherElsevier Ltd.pt_BR
dc.rightsAcesso Restritopt_BR
dc.titleBanach spaces-based analysis of a fully-mixed finite element method for the steady-state model of fluidized bedspt_BR
dc.typeArtigopt_BR
dc.subject.keywordBanach, Espaços dept_BR
dc.subject.keywordMétodo dos elementos finitospt_BR
dc.subject.keywordTeoria do ponto fixopt_BR
dc.identifier.doihttps://doi.org/10.1016/j.camwa.2021.01.001pt_BR
dc.relation.publisherversionhttps://www.sciencedirect.com/science/article/abs/pii/S0898122121000031pt_BR
dc.description.abstract1In this paper we propose and analyze a fully-mixed finite element method for the steady-state model of fluidized beds. This numerical technique, which arises from the use of a dual-mixed approach in each phase, is motivated by a methodology previously applied to the stationary Navier–Stokes equations and related models. More precisely, we modify the stress tensors of the fluid and solid phases by defining pseudostresses as phasic stresses that include shear, pressure, and convective effects. Next, we eliminate the pressures from the equations and derive constitutive relations depending only on the aforementioned pseudostresses and the velocities of the fluid and the particles. In this way, these variables, together with the skew-symmetric parts of the velocity gradients, also named vorticities, become the only unknowns of our variational formulation. As usual, the latter is obtained by testing against suitable functions, and then integrating and integrating by parts, respectively, the equilibrium and the constitutive equations. The particle pressure, a known function of the concentration, is given as a datum, and the fluid pressure is computed afterwards via a postprocessing formula. The continuous setting, lying in a Banach spaces framework rather than in a Hilbertian one, is rewritten as an equivalent fixed-point equation, and hence the well-posedness analysis is carried out by combining the Babuka–Brezzi theory, the Banach–Neas–Babuka Theorem, and the classical Banach fixed-point Theorem. Thus, existence of a unique solution in a closed ball is guaranteed for sufficiently small data. In turn, the associated Galerkin scheme is introduced and analyzed analogously, so that, under suitable assumptions on generic finite element subspaces, and for sufficiently small data as well, the Brouwer and Banach fixed-point Theorems allow to conclude existence and uniqueness of solution, respectively. Specific finite element subspaces satisfying the required hypotheses are described, and optimal a priori error estimates are derived. Finally, several numerical examples illustrating the performance of the method and confirming the theoretical rates of convergence, are reported.pt_BR
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