Impact of dust kinematic viscosity on the breathers and rogue waves in a complex plasma having kappa distributed particles

In this paper, a numerical examination of propagating nonlinear dissipative dust-acoustic breathers and rogue waves (RWs) in electron depleted dusty plasmas having two superthermal ions of different temperature has been made. An important ingredient in this study is the inclusion of the dissipative effect due to the viscosity of the dust grains in the evolution wave equation. Accordingly, a damped/modified nonlinear Schrodinger equation (DNLSE), i.e. the standard nonlinear Schrodinger equation (NLSE) in addition to the damping term, is obtained using a reductive perturbation (the derivative expansion) method. Without taking into account the effect of dust viscosity, the standard NLSE is also examined, and the effect of relevant physical parameters on the breathers and rogue waves is examined. Moreover, the impact of dust kinetic viscosity on both breather structures and RWs is investigated by solving DNLSE numerically with the Dirichlet boundary conditions. This model may be useful to understand the excitation of dust-acoustic waves in the Earth's magnetotail.

Automated summary

This study numerically examines propagating nonlinear dissipative dust-acoustic breathers and rogue waves in electron-depleted dusty plasmas with two superthermal ions of different temperatures, considering the effects of dust viscosity and damping. The research presents a damped/modified nonlinear Schrodinger equation (DNLSE) to investigate the impact of dust kinetic viscosity on breather structures and rogue waves, providing insights into the excitation of dust-acoustic waves in Earth's magnetotail.