We study a hierarchy of electrical conduction problems in biological tissues. These problems are set in a nely mixed periodic medium, and the unknown electric potentials solve standard elliptic equations set in dierent conductive regions (the intracellular and extracellular spaces), separated by an interface (the cell membranes), which exhibits a capacitive and a nonlinear conductive behavior, due to its biochemical structure. Dierent scalings in the interface condition correspond to dierent problems in the hierarchy. As the spatial period of the medium goes to zero, the problems approach a homogenization limit depending on the initial scaling. The macroscopic models are obtained by using the technique of two-scale convergence.
A hierarchy of models for the electrical conduction in biological tissues via two-scale convergence: The nonlinear case / Amar, M.; Andreucci, D.; Bisegna, P.; Gianni, R.. - In: DIFFERENTIAL AND INTEGRAL EQUATIONS. - ISSN 0893-4983. - ELETTRONICO. - 26:(2013), pp. 885-912.
A hierarchy of models for the electrical conduction in biological tissues via two-scale convergence: The nonlinear case
Gianni, R.
2013
Abstract
We study a hierarchy of electrical conduction problems in biological tissues. These problems are set in a nely mixed periodic medium, and the unknown electric potentials solve standard elliptic equations set in dierent conductive regions (the intracellular and extracellular spaces), separated by an interface (the cell membranes), which exhibits a capacitive and a nonlinear conductive behavior, due to its biochemical structure. Dierent scalings in the interface condition correspond to dierent problems in the hierarchy. As the spatial period of the medium goes to zero, the problems approach a homogenization limit depending on the initial scaling. The macroscopic models are obtained by using the technique of two-scale convergence.
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