Triple-band transparency effect by multiple couplings based on toroidal dipole resonance

Author:

Li Jie,Chang Shiqi,Wang YinghuaORCID,Wang YongjinORCID

Abstract

Abstract We explored multiple couplings properties in composite metastructure. One part is the asymmetric double rings, supporting the narrow toroidal dipole resonance, and the other component is an upright rod that excites the broad electric dipole resonance. When these two resonant modes coincide in the spectrum, dual-band plasmon induced transparency (PIT) behavior can be obtained, which is attributed to in-phase and out-of-phase couplings between the toroidal dipole and electric dipole modes. Meanwhile, the dual-band features will become a single PIT band by varying the rotation offset angle between the upper- and lower-rings. Moreover, by introducing lateral displacement of the rod with respect to the toroidal component, a triple-band PIT effect can be achieved. In particular, under a large lateral displacement, a broadband transparency window appears across a wavelength range greater than 120 nm, where the transmission exceeds 0.9. It is derived from the hybrid coupling between toroidal dipole, electric dipole and induced high-order resonance modes. The toroidal-based PIT metamaterials not only promote the understanding of toroidal dipole moment but also provide a positive reference for toroidal-based meta-devices.

Funder

Natural Science Foundation of Jiangsu Province

Publisher

IOP Publishing

Reference49 articles.

1. The relation between decay asymmetry and dipole moment of elementary particles;Zel’dovich;Sov. Phys. JETP,1958

2. Toroidal dipolar response in a metamaterial;Kaelberer;Science,2010

3. Low-loss and high-Q planar metamaterial with toroidal moment;Fan;Phys. Rev.,2013

4. All-optical hall effect by the dynamic toroidal moment in a cavity-based metamaterial;Dong;Phys. Rev.,2013

5. Optical toroidal dipolar response by an asymmetric double-bar metamaterial;Dong;Appl. Phys. Lett.,2012

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