Please use this identifier to cite or link to this item: http://hdl.handle.net/2381/9291
Title: Quasichemical Models of Multicomponent Nonlinear Diffusion
Authors: Wahab, Hafiz Abdul
Supervisors: Gorban, Alexander
Georgoulis, Emmanuil
Award date: 1-Apr-2011
Presented at: University of Leicester
Abstract: Diffusion preserves positivity of concentrations, therefore, multicomponent diffusion should be nonlinear if there exist non-diagonal terms. The vast variety of nonlinear multicomponent diffusion equations should be ordered and special tools are necessary to provide systematic construction of the nonlinear diffusion equations for multicomponent mixtures with significant interaction between components. We develop an approach to nonlinear multicomponent diffusion based on the idea of reaction mechanism borrowed from chemical kinetics. Chemical kinetics gave rise to the very seminal tools for the modelling of processes. This is the stoichiometric algebra supplemented by the simple kinetic law. The results of this invention are now applied in many areas of science, from particle physics to sociology. In our work we extend the area of applications onto nonlinear multicomponent diffusion. We demonstrate, how the mechanism based approach to multicomponent diffusion can be included into the general thermodynamic framework, and prove the corresponding dissipation inequalities. To satisfy the thermodynamic restrictions, the kinetic law of an elementary process cannot have an arbitrary form. For the general kinetic law (the generalized Mass Action Law), additional conditions are proved. The cell-jump formalism gives an intuitively clear representation of the elementary transport processes and, at the same time, produces kinetic finite elements, a tool for numerical simulation.
Links: http://hdl.handle.net/2381/9291
Type: Thesis
Level: Doctoral
Qualification: PhD
Appears in Collections:Theses, Dept. of Mathematics
Leicester Theses

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