Tunable magnon-phonon cavity via structural phase transition

Strong coupling between two quantized excitations in a cavity has the potential to lead to hybridized states that bestow novel quantum phenomena. In particular, tunable hybrid magnon-phonon cavities with precise control knobs are in pressing demand for developing quantum functionalities in solid-state platforms. Here, using a combination of synthesis and characterization tools, we present an epitaxial La_0.7Sr_0.3MnO₃/SrTiO₃ (LSMO/STO) heterostructure that manifests strong couplings between the Kittel magnon and the transverse acoustic phonon. Remarkably, leveraging the magnetoelastic interaction at the epitaxial interface, we demonstrate that when the STO substrate undergoes a cubic-to-tetragonal phase transition at ~105 K, the Kittel magnon of the LSMO thin film splits into three bands due to anisotropic structural strains along the [100], [010], and [001] crystalline axes, hence, resulting in an array of non-degenerate, hybridized magnon-phonon modes. Moreover, we develop an analytical model that can reproduce the interfacial strain-induced magnon splitting and the strength of magnon-phonon coupling. Our work highlights structural phase transitions as a sensitive trigger for generating multistate magnon-phonon hybridization in high-quality magnetoelastic oxide heterostructures - a new route for implementing strain-mediated hybrid magnonics in phononic systems with potential applications in coherent energy and signal transduction.