Exploring topology of 1D quasiperiodic metastructures through modulated LEGO resonators

We investigate the dynamics and topology of metastructures with quasiperiodically modulated local resonances. The concept is implemented on a LEGO beam featuring an array of tunable pillar-cone resonators. The versatility of the platform allows the experimental mapping of the Hofstadter-like resonant spectrum of an elastic medium, in the form of a beam waveguide. The non-trivial spectral gaps are classified by evaluating the integrated density of states of the bulk bands, which is experimentally verified through the observation of topological edge states localized at the boundaries. Results also show that the spatial location of the edge states can be varied through the selection of the phase of the resonator's modulation law. The presented results open new pathways for the design of metastructures with functionalities going beyond those encountered in periodic media by exploiting aperiodic patterning of local resonances and suggest a simple, viable platform for the observation of a variety of topological phenomena.

Automated summary

The study investigates dynamics and topology of metastructures with quasiperiodically modulated local resonances using a LEGO beam platform. Experimental mapping of resonant spectrum of an elastic medium was achieved, classifying non-trivial spectral gaps and verifying them through observation of topological edge states. The results demonstrate the potential for designing metastructures with functionalities beyond periodic media and provide a simple platform for observing various topological phenomena.