Title: Reconfigurable spin-wave platform based on interplay between nanodots and waveguide in hybrid magnonic crystal

Abstract: We present a hybrid magnonic crystal composed of a chain of nanodots with strong perpendicular magnetic anisotropy and Dzyaloshinskii-Moriya interaction, positioned above a permalloy waveguide. The study examines two different magnetization states in the nanodots: a single-domain state and an egg-shaped skyrmion state. Due to the dipolar coupling between the dot and the waveguide, a strongly bound hybrid magnetization texture is formed in the system. Our numerical results show complex spin-wave spectra, combining the effects of periodicity, magnetization texture, and hybridization of the propagating waves in the waveguide with the dot/skyrmion modes. The systems are characterized by different band gap sizes. For the skyrmion state, the azimuthal modes confined to the skyrmion domain wall lead to the formation of flat bands at low frequencies, while at higher frequencies we identify among them modes interacting with the propagating waves, which can introduce additional non-Bragg band gaps, as well as isolated modes leading to the formation of bound states. On the other hand, the system with a single-domain state in nanodots offers a wide range of frequencies where the spin waves are predominantly in the waveguide. Thus, the study shows that the proposed hybrid magnonic crystals have many distinct functionalities, highlighting their reconfigurable potential, magnon-magnon couplings, mode localization, and bound states overlapping with the propagating waves. This opens up potential applications in analog and quantum magnonics, spin-wave filtering, and the establishment of magnonic neural networks.