Dynamical symmetry breaking described by cubic nonlinear Klein-Gordon equations
Abstract
The dynamical symmetry breaking associated with the existence and non-existence of breather solutions is studied. Here, nonlinear hyperbolic evolution equations are calculated using a high-precision numerical scheme. %%% First, for clarifying the dynamical symmetry breaking, it is necessary to use a sufficiently high-precision scheme in the time-dependent framework. Second, the error of numerical calculations is generally more easily accumulated for calculating hyperbolic equations rather than parabolic equations. Third, numerical calculations become easily unstable for nonlinear cases. Our strategy for the high-precision and stable scheme is to implement the implicit Runge-Kutta method for time, and the Fourier spectral decomposition for space. %%% In this paper, focusing on the breather solutions, the relationship between the velocity, mass, and the amplitude of the perturbation is clarified. As a result, the conditions for transitioning from one state to another are clarified.