Abstract: High-quality Al1-xInxN layers and AlInN/GaN Bragg mirrors near lattice-matched to GaN layers are grown by metalorganic vapor-phase epitaxy on a GaN buffer layer with no cracks over full 2-inch sapphire wafers. The index contrast relative to GaN is 6.5% to 11% for wavelengths ranging from 950 nm to 380 nm. A crack-free, 20 pairs Al0.84In0.16N/GaN distributed Bragg reflector is grown, centered at 515 nm with over 90% reflectivity and a 35 nm stopband. High-quality AlInN lattice matched to GaN can be used in GaN-based optoelectronics, for waveguides and for mirror structures in resonant-cavity light-emitting diodes and monolithic Fabry-Pérot cavities, for example.

Abstract: An electroluminescent device including a layer of electroluminescent organic semiconductor material between a first transparent electrode of an n-type semiconductor material selected from nitrides and inorganic oxides, and a second electrode.

Abstract: A buried double heterostructure laser device isdescribed. A wafer of double heterostructure material is formed into narrow mesa stripes. A native oxide coating is formed on the side walls of the mesa. Semiconductor material having an index of refraction which is closely matched to the index of the active region is deposited over the mesa structure. High resistivity polycrystalline material forms on the native oxide and monocrystalline material forms on the top of the mesa. Vertical carrier and optical confinement is achieved by the higher bandgap cladding layers of the double heterostructure configuration. The native oxide acts as an electrical insulator to confine pumping current to the mesa. The closely matched polycrystalline material confines light parallel to the junction plane and prevents excitation of higher order transverse modes. Devices have been fabricated which exhibit cw threshold currents at room temperature as low as 55 mA.

Abstract: A plurality n of double heterostructure photodiodes are coupled together by (n-1) interleaved n.sup.+ -p.sup.+ tunnel junctions to form a multi-layered integrated structure which has an open circuit photovoltage approaching the sum of the open circuit photovoltages of the individual photodiodes. In one embodiment, in which radiation to be detected is made incident normal to the layers, the absorbing layers of the photodiodes get progressively thicker away from the substrate. In a second embodiment, in which the radiation is made incident parallel to the layers, all of the absorbing layers have essentially the same thickness. In a third embodiment, in which radiation is made incident normal to the layers, the structure has a stepped configuration and all of the absorbing layers have essentially the same thickness.