论文信息 - Strained quaternary quantum well lasers for high temperature operation

Strained quaternary quantum well lasers for high temperature operation

We describe compressively strained separate confinement heterostructure 1.3 μm quantum well lasers optimized for high temperature operation. The active layer consists of ten GaInAsP wells, each 40–80 A thick, grown under compressive lattice mismatch strain of Δa/a≤0.75%. Within the constraints of the well composition and thickness imposed on the active region, strain is necessary for efficient laser operation. Best results are obtained for Δa/a∼0.2%–0.3% with the laser threshold as low as 5 mA and slope efficiency of 42 mW/mA. In the temperature range of 25–85 °C a slope efficiency change as small as 30% was achieved. Power output of at least 20 mW can be maintained up to 100 °C at a current drive below 150 mA.

[1] R. D. Yadvish,et al. High-speed InGaAsP/InP multiple-quantum-well laser , 1992, IEEE Photonics Technology Letters.

[2] T. Tanbun-ek,et al. Strained InGaAs/InP quantum well lasers , 1990 .

[3] S. Chu,et al. Critical layer thickness in strained Ga1−xInxAs/InP quantum wells , 1989 .

[4] Tawee Tanbun-Ek,et al. Strained multiple quantum well lasers emitting at 1.3 μm grown by low‐pressure metalorganic vapor phase epitaxy , 1991 .

[5] T. Tanbun-Ek,et al. High temperature operation of lattice matched and strained InGaAs-InP quantum well lasers , 1991, IEEE Photonics Technology Letters.

[6] P.J.A. Thijs,et al. High quantum efficiency, high power, modulation doped GaInAs strained-layer quantum well laser diodes emitting at 1.5 mu m , 1989 .

[7] L. Figueroa,et al. High-temperature operation of InGaAs strained quantum-well lasers , 1991, IEEE Photonics Technology Letters.

[8] R. D. Yadvish,et al. High temperature characteristics of InGaAsP/InP laser structures , 1993 .

[9] C. Y. Chen,et al. Low threshold 1.5 mu m tensile-strained single quantum well lasers , 1991 .

[10] T. Tanbun-ek,et al. High frequency buried heterostructure 1.5 μm GaInAsP/InP lasers, grown entirely by metalorganic vapour phase epitaxy in two epitaxial growth steps , 1988 .

[11] M. Panish,et al. High-resolution x-ray diffraction studies of InGaAs(P)/InP superlattices grown by gas-source molecular-beam epitaxy , 1987 .