Title :
Optical properties of epitaxial LaF3/SrF2/GaAs(111) heterostructure waveguides fabricated by molecular beam epitaxy
Author :
Fork, D.K. ; Armani-Leplingard, F. ; Lui, M. ; McFarlane, R.A.
Author_Institution :
Xerox Palo Alto Res. Center, CA, USA
fDate :
4/1/1996 12:00:00 AM
Abstract :
Thin film slab waveguides of lanthanum fluoride clad with strontium fluoride grown epitaxially on GaAs (111) are characterized by optical and structural techniques. Crystallinity, surface roughness, refractive indexes and propagation loss measurements suggest that these structures show promise for monolithically integrated infrared (IR) pumped IR down-conversion and visible upconversion laser devices. Propagation losses as low as 3.7 dB/cm at 633 nm were measured in samples which show waveguide propagation over distances of several centimeters. Simulation of the scattering losses due to surface roughness provides an approximate delineation of surface and nonsurface contributions to the optical loss. Typical root-mean-square surface roughness of the lanthanum fluoride layer was on the order of 3 nm. The morphology appears to be dominated by grain boundaries
Keywords :
epitaxial growth; gallium arsenide; integrated optoelectronics; lanthanum compounds; light scattering; optical fabrication; optical films; optical frequency conversion; optical losses; optical planar waveguides; optical pumping; strontium compounds; surface topography; 3 nm; 633 nm; GaAs; GaAs (111); LaF3-SrF2-GaAs; crystallinity; epitaxial LaF3/SrF2/GaAs(111) heterostructure waveguides; lanthanum fluoride clad; lanthanum fluoride layer; molecular beam epitaxy; monolithically integrated IR pumped down-conversion; nonsurface contributions; optical loss; optical properties; optical techniques; propagation loss measurements; propagation losses; refractive indexes; root-mean-square surface roughness; scattering losses; strontium fluoride; structural techniques; surface contributions; surface roughness; visible upconversion laser devices; waveguide propagation; Optical films; Optical pumping; Optical refraction; Optical scattering; Optical surface waves; Optical variables control; Optical waveguides; Rough surfaces; Surface morphology; Surface roughness;
Journal_Title :
Lightwave Technology, Journal of
