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Realization of ultrathin waveguides by elastic metagratings

Yabin Hu, Yunhao Zhang, Guangyuan Su, Meiying Zhao, Bing Li, Yongquan Liu, Zheng Li

2022Communications Physics64 citationsDOIOpen Access PDF

Abstract

Abstract Guiding classical waves has inspired a wealth of nontrivial physics and significant applications. To date, a robust and compact way to guide energy flux traveling along an arbitrary, prescheduled trajectory in a uniform medium is still a fundamental challenge. Here we propose and experimentally realize a generic framework of ultrathin waveguides for omnidirectional wave trapping and efficient routing. The metagrating-based waveguide can totally suppress all high-order parasitic diffractions to route guided elastic waves without leakage. The proposed waveguide protype works in a broad frequency range under a full-angle radiated source. An analytical slab-waveguide model is presented to predict and tailor the diffracted patterns. Compared with existing methods based on topological edge states or defected metamaterials, our meta-waveguide strategy exhibits absolute advantages in compact size, robust performance, and easy fabrication, which may provide a design paradigm for vibration and noise control, energy harvesting, microfluidics, wave steering in acoustics and other waves.

Topics & Concepts

MetamaterialWaveguideRealization (probability)Omnidirectional antennaOpticsDiffractionAcousticsPhysicsEnergy fluxComputer scienceTelecommunicationsMathematicsStatisticsAstronomyAntenna (radio)Metamaterials and Metasurfaces ApplicationsAcoustic Wave Phenomena ResearchMicrowave Engineering and Waveguides
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