Optical phase modulators are essential to large-scale integrated photonic systems at visible wavelengths, promising for many emerging applications. However, current technologies require large device footprints and either high power consumption or high drive voltage, limiting the number of active elements in a visible integrated photonic circuit. Here, we demonstrate visible silicon-nitride thermo-optical phase modulators based on adiabatic micro-ring resonators that offer at least a one-order-of-magnitude reduction in both device footprint and power consumption compared to waveguide phase modulators. Designed to operate in the strongly over-coupled regime, the micro-resonators provide 2 pi phase modulation with minimal amplitude variations, corresponding to less than 1 dB device insertion losses. By delocalizing the resonant mode, the adiabatic micro-rings also exhibit substantially improved robustness against fabrication variations.
Quantum cascade laser (QCL) is a semiconductor based laser in a superlattice structure based on intersubband transitions. Although QCLs have been achieved with high performance such as Watt-level emission, it is always highly desired to further improve the device performance with multiple functions , for example, achieving high beam collimation, arbitrary polarization control, and high speed modulation. It is also desired that those performance could be achieved through an integrated approach for miniaturalization, easy alignment and reducing cost.
In this presentation, we will use Terahertz (THz) QCL as a demonstration example to obtain high collimated THz QCLs through plasmonic collimation designs with a record beam divergence, electrically tunable THz polarizations by designing integrated THz metasurfaces on a hybrid dielectric-plasmonic waveguides, and broadband graphene-based integrated THz modulators with a fast modulating speed.
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