Abstract
The optical properties of topological photonics have attracted much interest recently because its potential applications for robust unidirectional transmission that are immune to scattering at disorder. However, researches on topological series coupled ring resonators (T-SCRR) have been much less discussed. The existence of topological interface-states (TIS) in the T-SCRR is described for the first time in this article. An approach has been developed to achieve this goal via the band structure of dielectric binary ring resonators and the Zak phase of each bandgap. It is found that an ultra-high-Q with complete transmission is obtained by the conjugated topological series coupled ring resonators due to the excitation of conjugated topological interface-states, which is different from those in conventional TIS. Furthermore, the problem of transmission decreases resulting from high-Q increases in the traditional photonic system is significantly improved by this approach. These findings could pave a novel path for developing advanced high-Q filters, optical sensors, switches, resonators, communications and quantum information processors.
Highlights
The optical properties of topological photonics have attracted much interest recently because its potential applications for robust unidirectional transmission that are immune to scattering at disorder
The Series coupled ring resonators (SCRR)-L consists of N-th half micro-rings denoted (a′bb′a)N, and the SCRR-R consists of N-th half mico-rings denoted (c′dd′c)N, respectively
Topological phase transition plays an important role in the optical properties of topological interface-states, which is characterized by the Zak phase change and the reflection phase change
Summary
The optical properties of topological photonics have attracted much interest recently because its potential applications for robust unidirectional transmission that are immune to scattering at disorder. This study finds that the TIS and the usual IS can be excited in the micro-ring resonators, their optical properties are unusually different including the transmittance and the quality factor.
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