Litcius/Paper detail

Acoustic cavities in 2D heterostructures

Maxim Zalalutdinov, Jeremy T. Robinson, José J. Fonseca, Samuel W. LaGasse, Tribhuwan Pandey, Lucas Lindsay, T. L. Reinecke, Douglas M. Photiadis, James C. Culbertson, Cory D. Cress, Brian H. Houston

2021Nature Communications61 citationsDOIOpen Access PDF

Abstract

Abstract Two-dimensional (2D) materials offer unique opportunities in engineering the ultrafast spatiotemporal response of composite nanomechanical structures. In this work, we report on high frequency, high quality factor ( Q ) 2D acoustic cavities operating in the 50–600 GHz frequency ( f ) range with f × Q up to 1 × 10 14 . Monolayer steps and material interfaces expand cavity functionality, as demonstrated by building adjacent cavities that are isolated or strongly-coupled, as well as a frequency comb generator in MoS 2 /h-BN systems. Energy dissipation measurements in 2D cavities are compared with attenuation derived from phonon-phonon scattering rates calculated using a fully microscopic ab initio approach. Phonon lifetime calculations extended to low frequencies (<1 THz) and combined with sound propagation analysis in ultrathin plates provide a framework for designing acoustic cavities that approach their fundamental performance limit. These results provide a pathway for developing platforms employing phonon-based signal processing and for exploring the quantum nature of phonons.

Topics & Concepts

PhononAttenuationMaterials scienceHeterojunctionDissipationQuantumMonolayerTerahertz radiationScatteringAb initioAcoustic attenuationOptoelectronicsCondensed matter physicsPhysicsOpticsNanotechnologyQuantum mechanicsThermodynamicsMechanical and Optical ResonatorsAcoustic Wave Resonator TechnologiesThermal properties of materials