Dancing synchronization in coupled spin-torque nano-oscillators

We report a type of synchronization, termed dancing synchronization, between two spin-torque nano-oscillators (STNOs) coupled through spin waves. Different from the known synchronizations in which two STNOs are locked with various fixed relative phases, in this synchronized state two STNOs have the same frequency, but their relative phase varies periodically within the common period, resulting in a dynamic waving pattern. The amplitude of the oscillating relative phase depends on the coupling strength of two STNOs, as well as the driven currents. The dancing synchronization turns out to be universal and can exist in two nonlinear Van der Pol oscillators coupled both reactively and dissipatively. Our findings open the door for new functional STNO-based devices.

Automated summary

This study introduces a new type of synchronization, referred to as dancing synchronization, occurring between two spin-torque nano-oscillators coupled through spin waves. In this synchronized state, the relative phase between the two oscillators varies periodically within a common period, resulting in a dynamic waving pattern. The amplitude of the oscillating relative phase is influenced by the coupling strength of the oscillators and the driven currents, and this dancing synchronization has been found to be universal and applicable to other nonlinear Van der Pol oscillators.