Litcius/Paper detail

Digitally virtualized atoms for acoustic metamaterials

Choonlae Cho, Xinhua Wen, Namkyoo Park, Jensen Li

2020Nature Communications67 citationsDOIOpen Access PDF

Abstract

By designing tailor-made resonance modes with structured atoms, metamaterials allow us to obtain constitutive parameters outside their limited range from natural materials. Nonetheless, tuning the constitutive parameters depends on our ability to modify the physical structure or external circuits attached to the metamaterials, posing a fundamental challenge to the range of tunability in many real-time applications. Here, we propose the concept of virtualized metamaterials on their signal response function to escape the boundary inherent in the physical structure of metamaterials. By replacing the resonating physical structure with a designer mathematical convolution kernel with a fast digital signal processing circuit, we demonstrate a decoupled control of the effective bulk modulus and mass density of acoustic metamaterials on-demand through a software-defined frequency dispersion. Providing freely software-reconfigurable amplitude, center frequency, bandwidth of frequency dispersion, our approach adds an additional dimension to constructing non-reciprocal, non-Hermitian, and topological systems with time-varying capability as potential applications.

Topics & Concepts

MetamaterialBandwidth (computing)Computer sciencePhysicsTopology (electrical circuits)Dimension (graph theory)AcousticsRange (aeronautics)Electronic circuitBoundary value problemNatural frequencyBoundary (topology)Acoustic metamaterialsPhysical systemNonlinear systemElectronic engineeringKernel (algebra)Convolution (computer science)Signal processingSplit-ring resonatorSIGNAL (programming language)Transformation opticsResonatorResonance (particle physics)Haptic technologyFunction (biology)Acoustic Wave Phenomena ResearchMetamaterials and Metasurfaces ApplicationsTopological Materials and Phenomena