Existence and stability of multisite breathers in honeycomb and hexagonal lattices

TL;DR

This paper investigates the existence and stability of multisite discrete breathers in honeycomb and hexagonal Klein-Gordon lattices, revealing stability conditions dependent on potential type and coupling sign, with numerical validation.

Contribution

It provides a comprehensive analysis of multisite breather stability in non-square lattices, including new stability results for various configurations and potential types.

Findings

Stable out-of-phase and charge-two vortex breathers in honeycomb lattice with soft potential.

Unstable in-phase and charge-one vortex states in honeycomb lattice.

Stability results are reversed for hard potential or negative coupling.

Abstract

We study the existence and stability of multisite discrete breathers in two prototypical non-square Klein-Gordon lattices, namely a honeycomb and a hexagonal one. In the honeycomb case we consider six-site configurations and find that for soft potential and positive coupling the out-of-phase breather configuration and the charge-two vortex breather are linearly stable, while the in-phase and charge-one vortex states are unstable. In the hexagonal lattice, we first consider three-site configurations. In the case of soft potential and positive coupling, the in-phase configuration is unstable and the charge-one vortex is linearly stable. The out-of-phase configuration here is found to always be linearly unstable. We then turn to six-site configurations in the hexagonal lattice. The stability results in this case are the same as in the six-site configurations in the honeycomb lattice. For all configurations in both lattices, the stability results are reversed in the setting of either hard potential or negative coupling. The study is complemented by numerical simulations which are in very good agreement with the theoretical predictions. Since neither the form of the on-site potential nor the sign of the coupling parameter involved have been prescribed, this description can accommodate inverse-dispersive systems (e.g., supporting backward waves) such as transverse dust-lattice oscillations in dusty plasma (Debye) crystals or analogous modes in molecular chains.