Anderson Localization of Visible Light on a Nanophotonic Chip

Abstract: We demonstrate Anderson localisation of visible light on a chip and report quality factors exceeding highly engineered two-dimensional cavities. Our results reverse the trend, observed so far, of the quality of disorder-induced light confinement being orders of magnitude lower than engineered devices. Furthermore, by implementing a sensitive imaging technique, we directly visualise the localised modes, determine their position on the device and measure their spatial extension.Our findings prove the potential o… Show more

“…By using the intrinsic photoluminescence of silicon nitride, we observe sharp resonances, a signature of the trapping of light in optical cavities, and measure quality factors approaching 10000 [4]. Such values exceed those reported for engineered 2D photonic crystal cavities operating at visible wavelengths.…”

High-Q Optical Cavities at Visible Wavelengths in Photonic Crystals in the Anderson-localized regime

“…By using the intrinsic photoluminescence of silicon nitride, we observe sharp resonances, a signature of the trapping of light in optical cavities, and measure quality factors approaching 10000 [4]. Such values exceed those reported for engineered 2D photonic crystal cavities operating at visible wavelengths.…”

High-Q Optical Cavities at Visible Wavelengths in Photonic Crystals in the Anderson-localized regime

“…We use a different approach that makes use of fabrication imperfections to trap light via multiple scattering and give the first demonstration of Anderson localization of visible light on a nanophotonic chip. By using the intrinsic photoluminescence of silicon nitride, we observe sharp resonances, a signature of the trapping of light in optical cavities, and measure quality factors approaching 10000 [4], far exceeding values reported for engineered 2D photonic crystal cavities.…”

High-Quality Confinement of Visible Light in Disordered Photonic Crystal Waveguides in the Anderson-Localized Regime

“…By using imperfections as a resource, we show that several high-quality optical cavities spontaneously appear along a fabricated photonic crystal waveguide operating at room temperature [4]. Such an approach represents a route for scalable, high quality optical sensors.…”

Disorder-Induced Light Confinement in Photonic Crystals as a Platform for Efficient Optical Sensing