Single-mode tunable, pulsed, and continuous wave quantum-cascade distributed feedback lasers at λ≅4.6–4.7 μm
- 28 February 2000
- journal article
- Published by AIP Publishing in Applied Physics Letters
- Vol. 76 (9) , 1092-1094
- https://doi.org/10.1063/1.125987
Abstract
Single-mode tunable quantum-cascade distributed feedback lasers emitting at 4.6–4.7 μm wavelength are reported. The lasers employ strained heterostructure material with global strain compensation to provide the large band offset needed for high-performance short wavelength operation. Pulsed, continuously tunable single-mode emission is achieved from 90 to 300 K with a tuning range of 65 nm. Peak output power levels of 100 mW at room temperature are obtained. In continuous-wave operation, current tunable single-mode emission is demonstrated around liquid-nitrogen temperature with a tuning range of 20 nm (over a current range of 450 mA). The maximum output power in continuous wave at 80 K is 150 mW.Keywords
This publication has 15 references indexed in Scilit:
- GaAs/AlGaAs distributed feedback quantum cascade lasersApplied Physics Letters, 2000
- Demonstration of high-performance 10.16 μm quantum cascade distributed feedback lasers fabricated without epitaxial regrowthApplied Physics Letters, 1999
- High-resolution (Doppler-limited) spectroscopy using quantum-cascade distributed-feedback lasersOptics Letters, 1998
- High-power λ≈8 μm quantum cascade lasers with near optimum performanceApplied Physics Letters, 1998
- Continuous-wave and high-power pulsed operation of index-coupled distributed feedback quantum cascade laser at λ≈8.5 μmApplied Physics Letters, 1998
- Short wavelength (λ∼3.4 μm) quantum cascade laser based on strained compensated InGaAs/AlInAsApplied Physics Letters, 1998
- Sensitive absorption spectroscopy with a room-temperature distributed-feedback quantum-cascade laserOptics Letters, 1998
- Quantum cascade laser with plasmon-enhanced waveguide operating at 8.4 μm wavelengthApplied Physics Letters, 1995
- Band-Gap Engineering: From Physics and Materials to New Semiconductor DevicesScience, 1987
- Coupled-Wave Theory of Distributed Feedback LasersJournal of Applied Physics, 1972