Fano resonance control in a photonic crystal structure and its application to ultrafast switching

TL;DR

This paper demonstrates robust control of Fano resonances in photonic crystal structures, enabling ultrafast all-optical switching with high contrast and low power, surpassing conventional Lorentzian resonances.

Contribution

It introduces two simple structures for controlling Fano resonances and demonstrates their application in 10 Gbit/s all-optical modulation with improved performance.

Findings

Enhanced switching contrast using Fano resonances

Reduced slow-recovery tails in nonlinear response

Successful high-speed optical data transmission at 10 Gbit/s

Abstract

Fano resonances appear in quantum mechanical as well as classical systems as a result of the interference between two paths: one involving a discrete resonance and the other a continuum. Compared to a conventional resonance, characterized by a Lorentzian spectral response, the characteristic asymmetric and sharp spectral response of a Fano resonance is suggested to enable photonic switches and sensors with superior characteristics. While experimental demonstrations of the appearance of Fano resonances have been made in both plasmonic and photonic-crystal structures, the control of these resonances is experimentally challenging, often involving the coupling of near-resonant cavities. Here, we experimentally demonstrate two simple structures that allow surprisingly robust control of the Fano spectrum. One structure relies on controlling the amplitude of one of the paths and the other uses symmetry breaking. Short-pulse dynamic measurements show that besides drastically increasing the switching contrast, the transmission dynamics itself is strongly affected by the nature of the resonance. The influence of slow-recovery tails implied by a long carrier lifetime can thus be reduced using a Fano resonance due to a hitherto unrecognized reshaping effect of the nonlinear Fano transfer function. For the first time, we present a system application of a Fano structure, demonstrating its advantages by the experimental realization of 10 Gbit/s all-optical modulation with bit-error-ratios on the order of 10$^{-7}$ for input powers less than 1 mW. These results represent a significant improvement compared to the use of a conventional Lorentzian resonance.