Optically-controlled extinction ratio and Q-factor tunable silicon microring resonators based on optical forces

Abstract: Tunability is a desirable property of microring resonators to facilitate superior performance. Using light to control light, we present an alternative simple approach to tuning the extinction ratio (ER) and Q-factor of silicon microring resonators based on optical forces. We design an opto-mechanical tunable silicon microring resonator consisting of an add-drop microring resonator and a control-light-carrying waveguide (“controlling” waveguide). One of the two bus waveguides of the microring resonator is a def… Show more

“…Having adjustable coupling would allow each switching element to be optimized for lower power penalty in function of the whole system, for example depending on the nature of the noise in the system. In [54] tunable coupling of a microring switch was demonstrated by realizing one of the waveguides as deformable nanostring. The tuning mechanism relies on the optical force induced deflection of the suspended nanostring.…”

Scaling silicon photonic switch fabrics for data center interconnection networks

“…Having adjustable coupling would allow each switching element to be optimized for lower power penalty in function of the whole system, for example depending on the nature of the noise in the system. In [54] tunable coupling of a microring switch was demonstrated by realizing one of the waveguides as deformable nanostring. The tuning mechanism relies on the optical force induced deflection of the suspended nanostring.…”

Scaling silicon photonic switch fabrics for data center interconnection networks

“…Assuming the ring is also lossless, so α=1 and T+R=1. The group refraction index is ng and the resonant wavelength is λ, the free spectral range (FSR) and ER of a single MRR can be expressed as [28]:…”

On-Chip Fano-Like Resonator With a High Slope and Low-Complexity Fabrication Processing

“…According to such signal flow, silicon photonic devices can be also classified by laser, modulator, switch, filter, (de)multiplexer, detector, and so on. The applications of silicon photonics include nonlinear optics [7][8][9][10][11][12][13][14][15][16][17][18], photonic signaling [6,[19][20][21][22][23][24][25][26][27][28][29][30][31][32][33][34][35][36], nanooptomechanics [37][38][39][40], photonic processing [41], sensors [42][43][44][45][46], mid-infrared optics [47][48][49][50][51], terahertz technology [52,53], and so on.…”

On-chip silicon photonic signaling and processing: a review