Title :
Wavelength Dependence of Transverse Mode Coupling With/Without E-Block of GaN Laser Cavity
Author :
Lal, Krishneel ; Chavoor, Greg ; Jin, Xiaomin
Author_Institution :
Electr. Eng. Dept., California Polytech. State Univ., San Luis Obispo, CA, USA
Abstract :
Transverse mode wavelength dependence in the gallium nitride (GaN) laser cavity is a new topic. Modal analysis simulations are run to optimize the blue GaN-based laser diode with a wavelength of 400, 430, and 460 nm. It is shown that the optical confinement factor (OCF) has a strong dependence on wavelength of emission and electron-block (e-block) thickness. The OCF can be changed from 4.9% at a 460-nm wavelength to 7.6% at 400 nm, which is a 55% difference. The effect of adding an e-block layer of different widths is also investigated with results showing that an e-block layer can change optical confinement by 14% at 460 nm wavelength and 13% at 400 nm wavelength. The bottom n-GaN layer thickness is optimized between 0.1 and 7 μm. It is found that a thin buffer layer improves optical mode distribution by reducing the ghost mode.
Keywords :
III-V semiconductors; buffer layers; electron emission; gallium compounds; laser cavity resonators; laser modes; modal analysis; quantum well lasers; wide band gap semiconductors; GaN; blue laser diode; buffer layer; e-block layer; electron-block emission; gallium nitride laser cavity; ghost mode; modal analysis; optical confinement factor; optical mode distribution; size 0.1 mum; size 7 mum; wavelength 400 nm; wavelength 430 nm; wavelength 460 nm; wavelength dependent transverse mode coupling; Gallium nitride; Laser modes; Optical buffering; Optical variables control; Optical waveguides; Semiconductor lasers; Waveguide lasers; Gallium-nitride laser diode; optical mode; optical mode confinement;
Journal_Title :
Photonics Journal, IEEE
DOI :
10.1109/JPHOT.2011.2177451
