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Topology-Changing Broadband Metamaterials Enabled by Closable Nanotrenches

Dasom Kim, Hyeong Seok Yun, Bamadev Das, Jiyeah Rhie, Parinda Vasa, Young‐Il Kim, Sung‐Hoon Choa, Namkyoo Park, Dukhyung Lee, Young‐Mi Bahk, Dai‐Sik Kim

2021Nano Letters37 citationsDOIOpen Access PDF

Abstract

One of the most straightforward methods to actively control optical functionalities of metamaterials is to apply mechanical strain deforming the geometries. These deformations, however, leave symmetries and topologies largely intact, limiting the multifunctional horizon. Here, we present topology manipulation of metamaterials fabricated on flexible substrates by mechanically closing/opening embedded nanotrenches of various geometries. When an inner bending is applied on the substrate, the nanotrench closes and the accompanying topological change results in abrupt switching of metamaterial functionalities such as resonance, chirality, and polarization selectivity. Closable nanotrenches can be embedded in metamaterials of broadband spectrum, ranging from visible to microwave. The 99.9% extinction performance is robust, enduring more than a thousand bending cycles. Our work provides a wafer-scale platform for active quantum plasmonics and photonic application of subnanometer phenomena.

Topics & Concepts

MetamaterialPhotonicsTopology (electrical circuits)Materials scienceNanotechnologyOptoelectronicsEngineeringElectrical engineeringMetamaterials and Metasurfaces ApplicationsPlasmonic and Surface Plasmon ResearchAdvanced Antenna and Metasurface Technologies
Topology-Changing Broadband Metamaterials Enabled by Closable Nanotrenches | Litcius