Title :
Improved performance of 1.3-μm In(Ga)As quantum-dot lasers by modifying the temperature profile of the GaAs spacer layers
Author :
Walker, C.L. ; Sandall, I.C. ; Smowton, P.M. ; Mowbray, D.J. ; Liu, H.Y. ; Liew, S.L. ; Hopkinson, M.
Author_Institution :
Dept. of Phys. & Astron., Cardiff Univ., UK
fDate :
7/1/2006 12:00:00 AM
Abstract :
We demonstrate greatly improved threshold current and modal gain performance of 1.3-μm quantum-dot (QD) lasers by growing the GaAs spacer layers in two parts, where subtle modification of the spacer layer growth temperature profoundly influences the QDs. Measurements reveal significantly increased ground state (1.3 μm) modal absorption by increasing the growth temperature of the second part of the spacer layer. Improved modal gain is achieved, enabling continuous-wave lasing from a 1-mm-long uncoated laser, even without p-doping. This approach provides a potentially viable route to superior edge-emitting lasers and GaAs-based 1.3-μm vertical-cavity surface-emitting lasers.
Keywords :
III-V semiconductors; gallium arsenide; ground states; indium compounds; laser transitions; quantum dot lasers; semiconductor growth; 1.3 mum; GaAs; GaAs spacer layers; In(Ga)As quantum-dot lasers; InGaAs; continuous-wave lasing; ground state; modal absorption; modal gain; threshold current; Absorption; Gallium arsenide; Land surface temperature; Performance gain; Quantum dot lasers; Quantum dots; Stationary state; Surface emitting lasers; Threshold current; Vertical cavity surface emitting lasers; Optical gain; optical loss; quantum dots (QDs); semiconductor lasers;
Journal_Title :
Photonics Technology Letters, IEEE
DOI :
10.1109/LPT.2006.879592
