In this paper, the design, fabrication, and characterization of 2-D multimode interference (MMI) devices based on integrated silicon hollow antiresonant reflection optical waveguides (ARROW) is presented. Unlike conventional waveguides, the field in ARROW is not confined in the core region by total internal reflection but by dielectric cladding layers designed to form-high reflectivity FabryPerot mirrors. This peculiar structure permits to realize integrated hollow-core waveguides using standard silicon technology. In this paper, we show that these waveguides can be usefully applied in the fabrication of 2-D MMI devices. With a 130 µm×130 µm cross-section waveguide, multiple images are observed from 1×1 to 6×6 image matrices. These devices also exhibit interesting bandpass pectral properties that can be usefully applied in several fields ranging from telecommunications to sensing.
2D MMI devices based on integrated hollow ARROW waveguides
Bernini R;
2007
Abstract
In this paper, the design, fabrication, and characterization of 2-D multimode interference (MMI) devices based on integrated silicon hollow antiresonant reflection optical waveguides (ARROW) is presented. Unlike conventional waveguides, the field in ARROW is not confined in the core region by total internal reflection but by dielectric cladding layers designed to form-high reflectivity FabryPerot mirrors. This peculiar structure permits to realize integrated hollow-core waveguides using standard silicon technology. In this paper, we show that these waveguides can be usefully applied in the fabrication of 2-D MMI devices. With a 130 µm×130 µm cross-section waveguide, multiple images are observed from 1×1 to 6×6 image matrices. These devices also exhibit interesting bandpass pectral properties that can be usefully applied in several fields ranging from telecommunications to sensing.I documenti in IRIS sono protetti da copyright e tutti i diritti sono riservati, salvo diversa indicazione.
