Geometry-controlled magnon-polariton excitations in a bilayer planar cavity

Original Abstract

Planar cavity magnonics has been developed predominantly for a single magnetic film, leaving the role of multiple magnetic layers in a cavity-scattering framework with spatial resolution largely unexplored. In this study, we introduce a bilayer planar cavity in which two magnetic films are embedded inside the same microwave cavity and interact through the cavity field and their relative placement within the standing-wave pattern. First, we derive a full two-film scattering theory in the macrospin limit and recover the exact zero-gap half-thickness limit to benchmark it against the known one-film planar result. This formulation reveals that the bilayer does not simply strengthen the magnon-photon interaction by adding magnetic material but instead enables position-dependent control of the collective bright channel. Antinode-compatible placements enhance effective coupling, whereas node-compatible placements suppress it. We then show that weak symmetry breaking between the two films transfers the finite cavity weight to a mode that is dark in the symmetric limit, producing an additional spectroscopic branch without immediately destroying the main avoided crossing. To extend the analysis beyond the macrospin regime, we formulate a reduced multimode bilayer theory for $J\neq 0$, where odd standing-spin-wave families reorganize into family-resolved bright and dark bilayer channels. Our results show that bilayer planar cavities are a minimal but versatile setting for controlling the collective magnon-polariton structure through geometry, symmetry, and exchange-driven mode hierarchy.