The quantum exchange effects on the electromagnetic solitonic excitations in warm plasma

The phenomena related to the high energy regime in a plasma medium are studied in the framework of relativistic quantum hydrodynamics at the classical level. This theory leads to nonlinear equations even at the weak relativistic regime. These nonlinearities give rise to interesting and novel phenomena in the dynamics of the medium. Here, we consider these effects on the dynamics of a warm plasma environment. In addition, we study the effects of the exchange interaction between electrons on the dynamic of such a plasma. This interaction is a quantum mechanical effect and its strength is influenced by the spin polarization ratio of the electrons. Both the analytical and the numerical solutions are presented which are stable and bounded soliton waves. For the analytical solutions, an extended tanh approach, and for the numeric approach, the techniques of solving eigenvalue problems are applied. The behavior of the vector potential and the density under the spin polarization effects and thermal effects in terms of the speed of the wave are discussed.

Automated summary

This study investigates the phenomena related to high energy regime in a plasma medium using relativistic quantum hydrodynamics at the classical level. Nonlinear equations are obtained due to the relativistic effects even in the weak regime, leading to interesting and novel dynamics of the medium. The focus is on the effects of the exchange interaction between electrons on the dynamics of a warm plasma environment, influenced by the spin polarization ratio. Analytical and numerical solutions, namely stable and bounded soliton waves, are presented, obtained through extended tanh and eigenvalue problem solving techniques respectively. The behavior of the vector potential and density with respect to spin polarization and thermal effects in terms of wave speed is discussed.