Cavity magnomechanical chaos
Jiao Peng, Zeng‐Xing Liu, Ya‐Fei Yu, Hao Xiong
Abstract
Cavity magnomechanics using mechanical degrees of freedom in ferromagnetic crystals provides a powerful platform for observing many interesting classical and quantum nonlinear phenomena in the emerging field of magnon spintronics. However, to date, the generation and control of chaotic motion in a cavity magnomechanical system remain an outstanding challenge due to the inherently weak nonlinear interaction of magnons. Here, we present an efficient mechanism for achieving magnomechanical chaos, in which the magnomechanical system is coherently driven by a two-tone microwave field consisting of a pump field and a probe field. Numerical simulations show that the relative phase of the two input fields plays an important role in controlling the appearance of chaotic motion and, more importantly, the threshold power of chaos is reduced by 6 orders of magnitude from watts to microwatts. In addition to providing insight into the nonlinear interaction of magnons, cavity magnomechanical chaos will always be of interest because of its significance in both fundamental physics and potential applications ranging from ultralow threshold chaotic motion to chaos-based secret information processing.