Abstract
Abstract The variational formulation of the interior Bernoulli free boundary problem is considered. The problem is formulated as follows. Choose an arbitrary bounded simply connected domain G ⊂ ℝ2 and smooth positive functions g : ∂G → ℝ, Q : G → ℝ. Denote by 𝒞 the totality of all connected compact sets ω ⊂ ., such that the flow domain Ω = G \ ω is double-connected. The notation 𝒞 + ⊂𝒞 stands for the totality of the set ω ∈𝒞 of positive measure. The cost function 𝒥 (ω) is defined by the equalities 𝒥 ( ω ) = ∫ Ω ( | ∇ u | 2 + Q 2 ) d x , Δ u = 0 in Ω , u = g on ∂ G , u = 0 on ∂ ω . \matrix{{\mathcal{J}\left( \omega \right) = \int_\Omega {\left( {{{\left| {\nabla u} \right|}^2} + {Q^2}} \right)dx,} } \hfill \cr {\Delta u = 0\,\,{\rm{in}}\,\,\Omega ,\,\,u = g\,\,{\rm{on}}\,\,\partial G,\,\,u = 0\,\,{\rm{on}}\,\,\,\partial \omega .} \hfill \cr } We prove that, under the natural nondegeneracy assumption, the variational problem min min ω ∈ 𝒞 + 𝒥 ( ω ) \mathop {\min }\limits_{\omega \in {\mathcal{C}^ + }} \,\,\mathcal{J}\left( \omega \right) has a solution ω ∈ 𝒞 +. The approach is based on the methods of complex variables theory and the potential theory. The key observation is that every subset of 𝒞, separated from ∂G is sequentially compact with respect to the Caratheodory-Hausdor convergence.
Published Version
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