Charged space debris induced nonlinear magnetosonic waves using inertial magnetohydrodynamics

TL;DR

This paper investigates how charged space debris influences nonlinear magnetosonic waves in Earth's low orbit, revealing stable solitary wave solutions that could aid in space debris detection and mitigation.

Contribution

It introduces a novel model incorporating electron inertia effects, deriving exact solutions for magnetosonic waves affected by space debris in inertial magnetohydrodynamics.

Findings

Stable magnetosonic lump solutions for slow and fast waves.

Existence of curved solitary waves with limited stability regions.

Potential applications in space debris detection and mitigation.

Abstract

The excitations of nonlinear magnetosonic waves in presence of charged space debris in the low Earth orbital plasma region is investigated taking into account effects of electron inertia in the framework of classical magnetohydrodynamics, which is also referred to as inertial magnetohydrodynamics. Magnetosonic waves are found to be governed by a forced Kadomtsev-Petviashvili equation with the forcing term representing effects of space debris particles. The dynamical behaviors of both slow and fast magnetosonic solitary waves is explored in detail. Exact accelerated magnetosonic lump solutions are shown to be stable for the entire region in parameter space of slow waves and a large region in parameter space of fast waves. In a similar way, magnetosonic curved solitary waves become stable for a small region in parameter space of fast waves. These exact solutions with special properties are derived for specific choices of debris functions. These novel results can have potential applications in scientific and technological aspects of space debris detection and mitigation.