Title :
Hot-cavity modelling of high-power tapered laser diodes using wide-angle 3D FD-BPM
Author :
Wykes, J. ; Borruel, L. ; Sujecki, S. ; Esquivias, I. ; Sewell, P. ; Benson, T.M. ; Larkins, E.C. ; Moreno, P. ; Krakowski, M.
Author_Institution :
Sch. of Electr. & Electron. Eng., Nottingham Univ., UK
Abstract :
The effective design of high power tapered laser diodes requires a detailed understanding of the coupled nonlinear optical, electrical and thermal processes which take place in the cavity. These nonlinearities result in phenomena such as spatial hole burning, self-focussing and filamentation, all of which play a significant role at higher output powers. Consequently, care must be taken in optimising the design of these devices to maximise the output power whilst maintaining good beam quality. Simulation gives the device designer the ability to experiment with the numerous degrees of freedom available in the design of these laser diodes, thus minimising the expense and time incurred for fabrication.
Keywords :
laser beams; laser cavity resonators; laser theory; optical design techniques; optical hole burning; optical self-focusing; semiconductor device models; semiconductor lasers; coupled nonlinear processes; electrical processes; filamentation; good beam quality; high-power tapered laser diodes; hot-cavity modelling; laser diode design; optical nonlinearities; output power; self-focusing; spatial hole burning; thermal processes; wide-angle 3D FD-BPM; Diode lasers; Finite difference methods; Laser beams; Nonlinear optics; Optical coupling; Optical design; Optical propagation; Optical refraction; Optical variables control; Power generation;
Conference_Titel :
Lasers and Electro-Optics Society, 2002. LEOS 2002. The 15th Annual Meeting of the IEEE
Print_ISBN :
0-7803-7500-9
DOI :
10.1109/LEOS.2002.1133933
