Edge states and topological pumping in elastic lattices with periodically modulated coupling

Abstract: We investigate the dispersion topology of elastic lattices characterized by spatial stiffness modulation. The modulation is defined by the sampling of a two-dimensional surface, which provides the lattices with topological properties that are usually attributed to two-dimensional crystals. We show that the cyclic variation of the phase of the stiffness modulation leads to a Berry phase accumulation for the Bloch eigenmodes, which is characterized by integer valued Chern numbers for the bands and associated gap labels. The resulting non-trivial gaps are spanned by edge modes localized at one of the boundaries of the considered 1D lattices. The edge mode location is governed by the phase of the stiffness distribution, whose spatial modulation drives these modes to transition from one edge to the other, through a bulk state that occurs when the corresponding dispersion branch touches the bulk bands. This property enables the implementation of a topological pump that is obtained by stacking and coupling a family of modulated 1D lattices along a second spatial dimension. The gradual variation of the stiffness phase modulation drives the adiabatic transition of the edge states, which transition from their localized state at one boundary, to a bulk mode and, finally, to another localized state at the opposite boundary. Similar effects were illustrated under the assumption of quasiperiodic modulation of the lattice interactions. We here demonstrate that a topological pump can be achieved also in periodic media, and illustrate this for the first time in elastic discrete lattices.