Orbital angular momentum conversion of acoustic vortex beams via planar lattice coupling

Orbital angular momentum(OAM) conversion is critical in understanding interactions between a structural sound field and a planar lattice. Herein, we explore the evolution of a monochromatic acoustic vortex beam(AVB) that is scattered by a phononic crystal(Pn C) or a correlated random lattice. The phenomenon is ascribed to the enhanced orbit–orbit angular momentum coupling induced by the band structure. By modifying the coupling condition, accurate and continuous micromanipulation of AVBs can be achieved, including the transverse/lateral gravity shift, the dynamics of the phase singularities,and the spatial distribution of acoustic pressure, etc. This research provides insight to the inhomogeneous coupling of AVBs with both propagating Bloch waves and localized Anderson modes, and may facilitate development of novel OAM-based acoustic devices for active sound field manipulation.