Nonlinear topological phase diagram in dimerized sine-Gordon model
Abstract
We investigate the topological physics and the nonlinearity-induced trap phenomenon in a coupled system of pendulums. It is described by the dimerized sine-Gordon model, which is a combination of the sine-Gordon model and the Su-Schrieffer-Heeger model. The initial swing angle of the left-end pendulum may be regarded as the nonlinearity parameter. The topological number is well defined as far as the pendulum is approximated by a harmonic oscillator. The emergence of the topological edge state is clearly observable in the topological phase by solving the quench dynamics starting from the left-end pendulum. A phase diagram is constructed in the space of the swing angle π with | |≤ 1 and the dimerization parameter λ with |λ |≤ 1. It is found that the topological phase boundary is rather insensitive to the swing angle for % | | 1/2. On the other hand, the nonlinearity effect becomes dominant for | | 1/2, and eventually the system turns into the nonlinearity-induced trap phase. Furthermore, when the system is almost dimerized (λ 1), coupled standing waves appear and are trapped to a few pendulums at the left-end, forming the dimer phase. Its dynamical origin is the cooperation of the dimerization and the nonlinear term.
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