Fractional Dynamics and Modulational Instability in Long-Range Heisenberg Chains

TL;DR

This paper investigates how long-range interactions in ferromagnetic spin chains lead to fractional nonlinear Schrödinger equations and cause modulational instability for certain interaction exponents, revealing new dynamical behaviors.

Contribution

It derives a fractional nonlinear Schrödinger equation from long-range Heisenberg chains and analyzes modulational instability, highlighting differences from short-range interactions.

Findings

Plane waves become modulationally unstable for  < 3.

The growth rate of instability depends on  and system parameters.

Long-range interactions induce fractional dynamics not present in short-range models.

Abstract

We study the effective dynamics of ferromagnetic spin chains in presence of long-range interactions. We consider the Heisenberg Hamiltonian in one dimension for which the spins are coupled through power-law long-range exchange interactions with exponent $\alpha$. We add to the Hamiltonian an anisotropy in the $z$-direction. In the framework of a semiclassical approach, we use the Holstein-Primakoff transformation to derive an effective long-range discrete nonlinear Schr\"odinger equation. We then perform the continuum limit and we obtain a fractional nonlinear Schr\"odinger-like equation. Finally, we study the modulational instability of plane-waves in the continuum limit and we prove that, at variance with the short-range case, plane waves are modulationally unstable for $\alpha < 3$. We also study the dependence of the modulation instability growth rate and critical wave-number on the parameters of the Hamiltonian and on the exponent $\alpha$.