Constant sign and sign changing NLS ground states on noncompact metric graphs

TL;DR

This paper studies the existence and nonexistence of ground states for the nonlinear Schrödinger equation on various noncompact metric graphs, providing conditions based on topology and geometry, and analyzing differences from Euclidean domains.

Contribution

It offers new abstract criteria for existence, characterizes topological and metrical conditions on graphs, and compares nodal properties with those in Euclidean spaces.

Findings

Identifies topological conditions preventing ground states on finite-edge graphs.

Provides sufficient conditions for existence of ground states based on graph properties.

Fully describes phenomena for periodic graphs and infinite trees.

Abstract

We investigate existence and nonexistence of action ground states and nodal action ground states for the nonlinear Schr\"odinger equation on noncompact metric graphs with rather general boundary conditions. We first obtain abstract sufficient conditions for existence, typical of problems with lack of compactness, in terms of ``levels at infinity'' for the action functional associated with the problems. Then we analyze in detail two relevant classes of graphs. For noncompact graphs with finitely many edges, we detect purely topological sharp conditions preventing the existence of ground states or of nodal ground states. We also investigate analogous conditions of metrical nature. The negative results are complemented by several sufficient conditions to ensure existence, either of topological or metrical nature, or a combination of the two. For graphs with infinitely many edges, all bounded, we focus on periodic graphs and infinite trees. In these cases, our results completely describe the phenomenology. Furthermore, we study nodal domains and nodal sets of nodal ground states and we show that the situation on graphs can be totally different from that on domains of $\mathbb{R}^N$.