Theoretical investigation of InGaN self-pulsating laser diodes for optical storage applications

Author

Jones, D.R. ; Rees, P. ; Pierce, I.

Author_Institution

Eblana Photonics, Trinity Coll. Enterprise Centre, Dublin

Volume

153

Issue

6

fYear

2006

fDate

12/1/2006 12:00:00 AM

Firstpage

330

Lastpage

337

Abstract

Self-pulsating laser diodes operating at 420 nm are required in high-density optical storage devices. By growing saturable absorbing quantum wells in the p-doped cladding layer, of a semiconductor laser, it is possible to obtain the interplay between gain and absorption, which is required for pulsation. The dynamics of self-pulsating InGaN laser diodes are investigated to gain an insight into how the quantum-well configuration in the absorber and the cavity length affect the laser output. In particular, the work shows how a carefully designed structure gives rise to stable self-pulsation up to a temperature of 100degC while offering high powered emission at low operating currents. As a result, such blue-emitting laser diodes are highly desirable for use within next-generation optical storage devices

Keywords

III-V semiconductors; gallium compounds; indium compounds; laser cavity resonators; optical pulse generation; optical saturable absorption; optical storage; quantum well lasers; wide band gap semiconductors; 100 degC; 420 nm; InGaN; InGaN self-pulsating laser diodes; blue-emitting laser diodes; cavity length; optical storage; p-doped cladding layer; saturable absorbing quantum wells;

fLanguage

English

Journal_Title

Optoelectronics, IEE Proceedings -

Publisher

iet

ISSN

1350-2433

Type

jour

DOI

10.1049/ip-opt:20060051

Filename

4027859