Controllable switching of the magnonic excitation based on the magnetostrictive effect

Abstract

The magnetostrictive effect in a yttrium iron garnet sphere induces a coherent interaction between magnetization and elastic strain. The dispersive-type coupling between the ferromagnetic magnon mode and the phonon mode is treated analytically, and the features of the magnonic excitation are discussed. We show that the resonant magnonic excitation of a signal driving field can be well controlled by another strong field via the interference of the excitation pathways, which results in convenient magnonic control and enables a magnonic switch with excellent functionality. The parameter optimization of the system has been performed to expand the operating bandwidth, and the influence of thermal noises to the magnonic switch has been discussed. Our analysis may provide a viable tool for controlling the magnonic excitation in magnetic materials and find applications in designing magnon-based devices.