On critical parameters in homogenization of perforated domains by thin tubes with nonlinear flux and related spectral problems

Abstract: Let uϵ be the solution of the Poisson equation in a domain normalΩ⊂double-struckR3 perforated by thin tubes with a nonlinear Robin‐type boundary condition on the boundary of the tubes (the flux here being β(ϵ)σ(x,uϵ)), and with a Dirichlet condition on the rest of the boundary of Ω. ϵ is a small parameter that we shall make to go to zero; it denotes the period of a grid on a plane where the tubes/cylinders have their bases; the size of the transversal section of the tubes is O(aϵ) with aϵ≪ϵ. A certain nonperi… Show more

“…However, it should be noted that for p = n, due to the fact that logarithmic scale appears (cf. (7.2)), a graphic of the type of Figure 2 summarizing all the possible homogenized problem becomes more complicated (even unthinkable), and, as occurs in [18] for the Laplacian and perforation by tubes, the graphics should be performed for well defined dependence of a ε and β ε in terms of ε. In this respect, as a sample, we outline that (1.9)-(1.11) provide the homogenized problem of (1.1) when we have the following relations: 12) with k = j ≥ 0, C 2 0 > 0, α 2 > 0, and ι = n/(n − 1).…”

“…However [21,44] consider only spherical cavities while the cavities can be of different shapes in [24,25] but for relations between parameters outside the big point. See [18,20] for a long list of references on related problems.…”

“…In the most critical situation, for nonlinear Robin boundary conditions, the Laplacian and n = 2, namely, p = n = 2, we refer to [37] for general geometries of the cavities and to [18] when p = 2, n = 3 and the domain is perforated by tubes. An extension to p = n ≥ 3 can be found in [39].…”

“…(1.1)), with unilateral constraints. Also, a more restrictive σ is considered in [18,37,39]. However, it should be emphasized that, in any case, the perimeter of the perforations arises in the strange term instead of the shape of the perforations as one might expect for n ≥ 3.…”

Unilateral problems for thep-Laplace operator in perforated media involving large parameters

“…However, it should be noted that for p = n, due to the fact that logarithmic scale appears (cf. (7.2)), a graphic of the type of Figure 2 summarizing all the possible homogenized problem becomes more complicated (even unthinkable), and, as occurs in [18] for the Laplacian and perforation by tubes, the graphics should be performed for well defined dependence of a ε and β ε in terms of ε. In this respect, as a sample, we outline that (1.9)-(1.11) provide the homogenized problem of (1.1) when we have the following relations: 12) with k = j ≥ 0, C 2 0 > 0, α 2 > 0, and ι = n/(n − 1).…”

“…However [21,44] consider only spherical cavities while the cavities can be of different shapes in [24,25] but for relations between parameters outside the big point. See [18,20] for a long list of references on related problems.…”

“…In the most critical situation, for nonlinear Robin boundary conditions, the Laplacian and n = 2, namely, p = n = 2, we refer to [37] for general geometries of the cavities and to [18] when p = 2, n = 3 and the domain is perforated by tubes. An extension to p = n ≥ 3 can be found in [39].…”

“…(1.1)), with unilateral constraints. Also, a more restrictive σ is considered in [18,37,39]. However, it should be emphasized that, in any case, the perimeter of the perforations arises in the strange term instead of the shape of the perforations as one might expect for n ≥ 3.…”

Unilateral problems for thep-Laplace operator in perforated media involving large parameters

“…Усреднение краевых и начально-краевых задач с классическими краевыми условиями типа Робина изучены во многих работах, см. [3][4][5][6][7][8][9][10] и список литературы там.…”

Homogenization limit for the Diffusion Equation in a domain Perforated along (n - 1)-Dimensional Manifold with Dynamic Conditions on the Boundary of the Perforations: Critical Case

Correcting Terms for Perforated Media by Thin Tubes with Nonlinear Flux and Large Adsorption Parameters