Title :
High-efficiency resonant-cavity LEDs emitting at 650 nm
Author :
Wirth, R. ; Karnutsch, C. ; Kugler, S. ; Streubel, K.
Author_Institution :
OSRAM Opto Semicond., Regensburg, Germany
fDate :
5/1/2001 12:00:00 AM
Abstract :
We fabricated resonant-cavity light-emitting diodes (LEDs) emitting at 650 nm. Compressively strained GaInP quantum wells were used as an active layer embedded between AlGaAs-AlAs Bragg mirrors. The Bragg mirrors formed a one-wavelength optical resonator. Two devices with different light-emitting areas were compared: 1) a large area chip (300 μm×300 μm) with a conventional LED contact and 2) a small area chip with an 80-μm light opening with an annular contact. Large devices are more suitable for high output power whereas the smaller devices might be useful for data transmission e.g., via plastic optical fibers. For epoxy-encapsulated large area devices, we achieved a maximum wall-plug efficiency of 10.2% and maximum output power of 12.2 mW at 100 mA. The small area LEDs yielded 2.9 mW at 20 mA and a maximum wall-plug efficiency of 9.5%.
Keywords :
III-V semiconductors; aluminium compounds; gallium arsenide; gallium compounds; indium compounds; light emitting diodes; mirrors; optical resonators; quantum well devices; 10.2 percent; 100 mA; 12.2 mW; 2.9 mW; 20 mA; 300 mum; 650 nm; 80 mum; 9.5 percent; AlGaAs-AlAs; AlGaAs-AlAs Bragg mirrors; GaInP; active layer; annular contact; compressively strained GaInP quantum wells; conventional LED contact; data transmission; epoxy-encapsulated large area devices; high output power; high-efficiency resonant-cavity LED; large area chip; large devices; light-emitting areas; maximum output power; maximum wall-plug efficiency; one-wavelength optical resonator; plastic optical fibers; small area chip; smaller devices; Brightness; Data communication; Epitaxial growth; Gallium arsenide; Light emitting diodes; Mirrors; Optical fibers; Optical resonators; Resonance; Stimulated emission;
Journal_Title :
Photonics Technology Letters, IEEE
