Collision of strong gravitational and electromagnetic waves in the expanding universe

TL;DR

This paper presents an exact analytical model of the nonlinear interaction between gravitational and electromagnetic waves in an expanding universe, revealing phenomena like wave creation, scattering, and oscillations based on Einstein-Maxwell equations.

Contribution

It introduces a novel exact solution modeling the collision of gravitational and electromagnetic waves in Kasner spacetime, showing complex nonlinear phenomena.

Findings

Soliton survives wave interactions but with altered parameters

Creation of gravitational waves from electromagnetic wave collisions

Electromagnetic soliton formation from gravitational wave interactions

Abstract

An exact analytical model of the process of collision and nonlinear interaction of gravitational and/or electromagnetic soliton wave and strong non-soliton electromagnetic traveling wave of arbitrary profile propagating in the expanding universe (the symmetric Kasner spacetime) is presented. In contrast to intuitive expectations that rather strong traveling waves can destroy the soliton, it occurs that the soliton survives during its interaction with electromagnetic wave of arbitrary amplitude and profile, but its parameters begin to evolve under the influence of this interaction. If a traveling electromagnetic wave possesses a finite duration, the soliton parameters after interaction take constant values again, but these values in general are different from those before the interaction. Based on exact solutions of Einstein - Maxwell equations, our model demonstrates a series of nonlinear phenomena, such as (a) creation of gravitational waves in the collision of two electromagnetic waves, (b) creation of electromagnetic soliton wave in the collision of gravitational soliton with traveling electromagnetic wave, (c) scattering of a part of soliton wave in the direction of propagation of traveling electromagnetic wave, (d) quasiperiodic oscillating character of fields in the wave interaction region and multiple mutual transformations of gravitational and electromagnetic waves in this region. The figures illustrate these features of nonlinear wave interactions in General Relativity.