Title :
Effect of surface recombination velocity on the threshold current and differential quantum efficiency of the surface-emitting laser diode
Author :
Ogura, Mutsuo ; Hsieh, H.C.
Author_Institution :
Electrotech. Lab., Tsukuba, Japan
fDate :
4/1/1996 12:00:00 AM
Abstract :
Threshold current and quantum efficiency of the surface-emitting laser diodes were calculated on the basis of a planar carrier diffusion model with cylindrical boundary and analytical electromagnetic field distribution in either a uniform core waveguide or Vainshtein´s open cavity model. Surface recombination at the boundary of the quantum-well active region was much greater than the bulk recombination in both structures unless cavity diameter was greater than 50 μm. Diffraction loss was also significant in the open cavity structure as cavity diameter decreased. Reducing the surface recombination velocity leads to the reduction of threshold current and enhancement of differential quantum efficiency. In order to further reduce that current, using a buried heterostructure with a vertical waveguide structure is suggested
Keywords :
diffusion; laser cavity resonators; laser theory; optical losses; quantum well lasers; semiconductor device models; surface emitting lasers; surface recombination; waveguide lasers; 50 mum; Surface recombination; Vainshtein´s open cavity model; analytical electromagnetic field distribution; bulk recombination; buried heterostructure; cavity diameter; cylindrical boundary; differential quantum efficiency; diffraction loss; open cavity structure; planar carrier diffusion model; quantum-well active region; surface recombination velocity; surface-emitting laser diode; threshold current; uniform core waveguide; vertical waveguide structure; Diode lasers; Electromagnetic analysis; Electromagnetic fields; Electromagnetic modeling; Electromagnetic waveguides; Planar waveguides; Radiative recombination; Surface emitting lasers; Surface waves; Threshold current;
Journal_Title :
Quantum Electronics, IEEE Journal of
