Litcius/Paper detail

Capturing Broadband Light in a Compact Bound State in the Continuum

Zeki Hayran, Francesco Monticone

2021ACS Photonics36 citationsDOIOpen Access PDF

Abstract

Trapping and storing light for arbitrary time lengths in open cavities is a major goal of nanophotonics, with potential applications ranging from energy harvesting to optical information processing. Unfortunately, however, the resonance lifetime of conventional open resonators remains finite, even in the limit of vanishing material absorption, as a result of radiation loss. In this context, bound states in the continuum (BiCs) have provided a unique way to achieve unbounded resonance lifetimes despite the presence of compatible radiation channels. However, physical constraints such as reciprocity, linearity, time-invariance and delay-bandwidth limits prevent the possibility to externally excite such ideal bound states and make them interact with broadband sources. Here, we overcome some of these limitations and theoretically demonstrate that subwavelength open resonators undergoing a suitable temporal modulation can efficiently capture a broadband incident wave into a nonradiating eigenmode of the structure, leading to the first example of a BiC that is accessible to broadband light. To further highlight the potential of the proposed concepts, we also show that such time-varying BiCs can be employed to bypass some of the bandwidth limitations of achromatic dispersion-engineered metalenses. Our findings unveil the dynamic capabilities of bound states in the continuum and extend their reach and potential impact for different applications.

Topics & Concepts

BroadbandPhysicsBound stateResonatorAchromatic lensRangingUpper and lower boundsRadiationOpticsBandwidth (computing)PhotonicsNormal modeResonance (particle physics)Coupled mode theoryLimit (mathematics)Optical cavityPhysical opticsElectromagnetically induced transparencyOptoelectronicsPolarization (electrochemistry)Computational physicsIdeal (ethics)Spontaneous emissionOptical physicsSlow lightPlasmonic and Surface Plasmon ResearchPhotonic Crystals and ApplicationsMechanical and Optical Resonators