Design criteria for highly-efficient operation of 1.3-/spl mu/m InP-based strained-layer multiple-quantum-well lasers at elevated temperatures
- 1 August 1995
- journal article
- Published by Institute of Electrical and Electronics Engineers (IEEE) in IEEE Photonics Technology Letters
- Vol. 7 (8) , 839-841
- https://doi.org/10.1109/68.403990
Abstract
We derive a basic design rule for highly-efficient operation of 1.3-/spl mu/m InP-based strained-layer (SL) multiple-quantum-well (MQW) lasers at elevated temperatures on the basis of a self-consistent numerical approach including the Poisson equation and effective-mass equations. Following the derived design rule, high-efficiency (0.55 W/A at 363 K) and high-power (over 35 mW at 363 K) InP-based SL-MQW lasers have been fabricated.Keywords
This publication has 15 references indexed in Scilit:
- High temperature performance of strained quaternary quantum well lasersPublished by Institute of Electrical and Electronics Engineers (IEEE) ,2002
- 1.3 μm InAsP compressively strained multiple-quantum-well lasers for high-temperature operationJournal of Applied Physics, 1995
- Metalorganic molecular beam epitaxy of strained InAsPInGaAsP multi-quantum-wells for 1.3 μm wavelength laser diodesJournal of Crystal Growth, 1995
- Band-structure engineering in strained semiconductor lasersIEEE Journal of Quantum Electronics, 1994
- Theoretical analysis of pure effects of strain and quantum confinement on differential gain in InGaAsP/lnP strained-layer quantum-well lasersIEEE Journal of Quantum Electronics, 1994
- MOVPE growth of strained InAsP/InGaAsP quantum-well structures for low-threshold 1.3-μm lasersIEEE Journal of Quantum Electronics, 1994
- Experimental study of Auger recombination, gain, and temperature sensitivity of 1.5 mu m compressively strained semiconductor lasersIEEE Journal of Quantum Electronics, 1993
- High temperature characteristics of InGaAsP/InP laser structuresApplied Physics Letters, 1993
- On the temperature sensitivity of semiconductor lasersApplied Physics Letters, 1992
- Two-dimensional analysis of optical waveguides with a nonuniform finite difference methodIEE Proceedings J Optoelectronics, 1991