Modulational instabilities in lattices with power-law hoppings and interactions

TL;DR

This paper investigates how power-law decaying interactions and hoppings influence modulational instabilities in one-dimensional lattices, revealing critical thresholds and the impact of long-range effects on stability regions.

Contribution

It provides a detailed analysis of modulational stability in lattices with non-local power-law interactions and hoppings, highlighting the conditions under which instabilities emerge and how long-range effects alter stability.

Findings

Power-law interactions shift the onset of modulational instabilities.

Long-range hoppings (1 < β < 2) eliminate modulational stability.

Competing interactions can induce instabilities at different wave vectors.

Abstract

We study the occurrence of modulational instabilities in lattices with non-local, power-law hoppings and interactions. Choosing as a case study the discrete nonlinear Schr\"odinger equation, we consider one-dimensional chains with power-law decaying interactions (with exponent \alpha) and hoppings (with exponent \beta): An extensive energy is obtained for \alpha, \beta>1. We show that the effect of power-law interactions is that of shifting the onset of the modulational instabilities region for \alpha>1. At a critical value of the interaction strength, the modulational stable region shrinks to zero. Similar results are found for effectively short-range nonlocal hoppings (\beta > 2): At variance, for longer-ranged hoppings (1 < \beta < 2) there is no longer any modulational stability. The hopping instability arises for q = 0 perturbations, thus the system is most sensitive to the perturbations of the order of the system's size. We also discuss the stability regions in the presence of the interplay between competing interactions - (e.g., attractive local and repulsive nonlocal interactions). We find that noncompeting nonlocal interactions give rise to a modulational instability emerging for a perturbing wave vector q = \pi while competing nonlocal interactions may induce a modulational instability for a perturbing wave vector 0 < q < \pi. Since for \alpha > 1 and \beta > 2 the effects are similar to the effect produced on the stability phase diagram by finite range interactions and/or hoppings, we conclude that the modulational instability is "genuinely" long-ranged for 1 < \beta < 2 nonlocal hoppings.