Inhomogeneous minimization problems for the p(x)-Laplacian

This paper is devoted to the study of inhomogeneous minimization problems associated to the p(x)-Laplacian. We make a thorough analysis of the essential properties of their minimizers and we establish a relationship with a suitable free boundary problem. On the one hand, we study the problem of mini...

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Bibliographic Details
Published in:Journal of mathematical analysis and applications 2019-07, Vol.475 (1), p.423-463
Main Authors: Lederman, Claudia, Wolanski, Noemi
Format: Article
Language:English
Subjects:
Free boundary problem
Inhomogeneous problem
Minimization problem
Regularity of the free boundary
Singular perturbation
Variable exponent spaces
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Summary:This paper is devoted to the study of inhomogeneous minimization problems associated to the p(x)-Laplacian. We make a thorough analysis of the essential properties of their minimizers and we establish a relationship with a suitable free boundary problem. On the one hand, we study the problem of minimizing the functional J(v)=∫Ω(|∇v|p(x)p(x)+λ(x)χ{v>0}+fv)dx. We show that nonnegative local minimizers u are solutions to the free boundary problem: u≥0 and(P(f,p,λ⁎)){Δp(x)u:=div(|∇u(x)|p(x)−2∇u)=fin {u>0}u=0,|∇u|=λ⁎(x)on ∂{u>0} with λ⁎(x)=(p(x)p(x)−1λ(x))1/p(x) and that the free boundary is a C1,α surface with the exception of a subset of HN−1-measure zero. On the other hand, we study the problem of minimizing the functional Jε(v)=∫Ω(|∇v|pε(x)pε(x)+Bε(v)+fεv)dx, where Bε(s)=∫0sβε(τ)dτ, ε>0, βε(s)=1εβ(sε), with β a Lipschitz function satisfying β>0 in (0,1), β≡0 outside (0,1). We prove that if uε are nonnegative local minimizers, then uε are solutions to(Pε(fε,pε))Δpε(x)uε=βε(uε)+fε,uε≥0. Moreover, if the functions uε, fε and pε are uniformly bounded, we show that limit functions u (ε→0) are solutions to the free boundary problem P(f,p,λ⁎) with λ⁎(x)=(p(x)p(x)−1M)1/p(x), M=∫β(s)ds, p=lim⁡pε, f=lim⁡fε, and that the free boundary is a C1,α surface with the exception of a subset of HN−1-measure zero. In order to obtain our results we need to overcome deep technical difficulties and develop new strategies, not present in the previous literature for this type of problems.
ISSN:0022-247X
1096-0813
DOI:10.1016/j.jmaa.2019.02.049