Abstract
We consider an energy functional combining the square of the local oscillation of a one-dimensional function with a double-well potential. We establish the existence of minimal heteroclinic solutions connecting the two wells of the potential. This existence result cannot be accomplished by standard methods, due to the lack of compactness properties. In addition, we investigate the main properties of these heteroclinic connections. We show that these minimizers are monotone, and therefore they satisfy a suitable Euler–Lagrange equation. We also prove that, differently from the classical cases arising in ordinary differential equations, in this context the heteroclinic connections are not necessarily smooth, and not even continuous (in fact, they can be piecewise constant). Also, we show that heteroclinics are not necessarily unique up to a translation, which is also in contrast with the classical setting. Furthermore, we investigate the associated Dirichlet problem, studying existence, uniqueness and partial regularity properties, providing explicit solutions in terms of the external data and of the forcing source, and exhibiting an example of discontinuous solution.
Highlights
One of the most classical problems in ordinary differential equations consists in the study of second-order equations coming from mechanical systems having a Hamiltonian structure
Noticing that q = ṗ, this system of ordinary differential equations reduces to the single second-order equation q = W (q)
We describe the main characteristics of the minimal heteroclinic connections given by Theorem 1.1
Summary
One of the most classical problems in ordinary differential equations consists in the study of second-order equations coming from mechanical systems having a Hamiltonian structure. While the previous literature mostly focuses on geometric evolution equations, viscosity solutions, perimeter type problems and questions arising in the calculus of variations, in this paper we aim at investigating the existence and basic properties of heteroclinic minimizers for nonlocal problems with lack of scale invariance. Since this topic of research is completely new, we will need to introduce the necessary methodology from scratch. We take into account the Dirichlet problem, obtaining explicit solutions and optimal oscillation bounds
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