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Tunable Metasurface Based on Plasmonic Quasi Bound State in the Continuum Driven by Metallic Quantum Wells

H. Ma, Junru Niu, Bingtao Gao, Yiyun Zhang, Yiming Feng, Fei Gao, Hongsheng Chen, Haoliang Qian

2023Advanced Optical Materials15 citationsDOI

Abstract

Abstract Effectual free‐space optical metasurface is essential for telecommunication and information processing. However, the lack of efficient optical nonlinearity is still an obstacle to empower its full capability and practical applications. Metallic quantum wells (MQWs) with large nonlinear susceptibility may pave a new way. Here, such MQWs are implemented into a resonance configuration of the quasi bound state in the continuum (BIC) and an efficient tunable plasmonic metasurface is proposed. Such metasurface is composed of MQWs‐based nanostructure, which supports the tunable plasmonic quasi‐BIC. The tunability is controlled through substantial change in refractive index of MQWs induced by Kerr‐type nonlinearity, which leads to around 9 dB extinction ratio and extremely high modulation speed up to terahertz level. The quasi‐BIC with narrow linewidth is obtained through symmetry‐breaking of nanoelliptical elements, further enhancing the modulation depth. This work satisfies the ultrafast‐speed and high‐efficiency requirement of free‐space all‐optical metasurfaces, including the spatial light modulators in optical computing field.

Topics & Concepts

PlasmonTerahertz radiationUltrashort pulseMaterials sciencePhotonicsOptoelectronicsOptical switchLaser linewidthModulation (music)OpticsNonlinear opticsNonlinear systemLaserPhysicsQuantum mechanicsAcousticsMetamaterials and Metasurfaces ApplicationsPlasmonic and Surface Plasmon ResearchOrbital Angular Momentum in Optics
Tunable Metasurface Based on Plasmonic Quasi Bound State in the Continuum Driven by Metallic Quantum Wells | Litcius