Title :
Modeling temperature effects and spatial hole burning to optimize vertical-cavity surface-emitting laser performance
Author :
Scott, Jeff W. ; Geels, Randall S. ; Corzine, Scott W. ; Coldren, Larry A.
Author_Institution :
California Univ., Santa Barbara, CA, USA
fDate :
5/1/1993 12:00:00 AM
Abstract :
Two-dimensional physical models for single-mode index guided vertical cavity surface emitting lasers (VCSELs) are developed and compared with experimental measurements on state-of-the-art devices. Starting with the steady-state electron and photon rate equations, the model calculates the above threshold light-current (LI) characteristics. Included are temperature effects, spatial hole burning effects, carrier diffusion, surface recombination, and an estimation of optical losses. The model shows that the saturation of output power in the experimental devices is due to carrier leakage over the heterojunction and not simply the shifting of the gain peak relative to the cavity mode. Using the verified model new designs are analyzed, showing that output powers greater than 15 mW and power efficiencies above 20% should be achievable with existing processing technology
Keywords :
laser cavity resonators; laser theory; optical hole burning; optical losses; semiconductor device models; semiconductor lasers; 15 mW; 20 percent; 2D physical models; above threshold; carrier diffusion; carrier leakage; cavity mode; gain peak; heterojunction; laser output power saturation; light-current; optical losses; photon rate equations; power efficiencies; semiconductor lasers; single-mode index guided vertical cavity surface emitting lasers; spatial hole burning; steady-state electron rate equations; surface recombination; temperature effects; vertical-cavity surface-emitting laser performance; Electrons; Equations; Laser modes; Laser theory; Power generation; Spontaneous emission; Steady-state; Surface emitting lasers; Temperature; Vertical cavity surface emitting lasers;
Journal_Title :
Quantum Electronics, IEEE Journal of
