An existence theory for nonlinear equations on metric graphs via energy methods

Abstract

The purpose of this paper is to develop a general existence theory for constrained minimization problems for functionals defined on function spaces on metric measure spaces ( M, d, μ). We apply this theory to functionals defined on metric graphs G, in particular L2-constrained minimization problems for functionals of the form E(u) = 12 a(u,u) - 1q∫ K |u|q \, dx, where q>2, a(·, ·) is a suitable symmetric sesquilinear form on some function space on G and K ⊂eq G is given. We show how the existence of solutions can be obtained via decomposition methods using spectral properties of the operator A associated with the form a(·, ·) and discuss the spectral quantities involved. An example that we consider is the higher-order variant of the stationary NLS (nonlinear Schr\"odinger) energy functional with potential V∈ L2+ L∞( G) E(k)(u)= 12 ∫ G |u(k)|2+ V(x) |u|2 \, dx - 1p ∫ K |u|q \, dx defined on a class of higher-order Sobolev spaces Hk( G) that we introduce. When K is a bounded subgraph, one has localized nonlinearities, which we treat as a special case. When k=1 we also consider metric graphs with infinite edge set as well as magnetic potentials. Then the operator A associated to the linear form is a Schr\"odinger operator, and in the L2-subcritical case 2<q<6, we obtain generalizations of existence results for the NLS functional as for instance obtained by Adami, Serra and Tilli [JFA 271 (2016), 201-223], and Cacciapuoti, Finco and Noja [Nonlinearity 30 (2017), 3271-3303], among others.