The Interplay of Regularizing Factors in the Model of Upper Hybrid Oscillations of Cold Plasma

Abstract

A one-dimensional nonlinear model of the so-called upper hybrid oscillations in a magnetoactive plasma is investigated taking into account electron-ion collisions. It is known that both the presence of an external magnetic field of strength B0 and a sufficiently large collisional factor help suppress the formation of a finite-dimensional singularity in a solution (breaking of oscillations). Nevertheless, the suppression mechanism is different: an external magnetic field increases the oscillation frequency, and collisions tend to stabilize the medium and suppress oscillations. In terms of the initial data and the coefficients B0 and , we establish a criterion for maintaining the global smoothness of the solution. Namely, for fixed B0 and 0 one can precisely divide the initial data into two classes: one leads to stabilization to the equilibrium and the other leads to the destruction of the solution in a finite time. Next, we examine the nature of the stabilization. We show that for small B0 an increase in the intensity factor first leads to a change in the oscillatory behavior of the solution to monotonic damping, which is then again replaced by oscillatory damping. At large values of B0 , the solution is characterized by oscillatory damping regardless of the value of the intensity factor .