Unipolar Quantum Cascade (QC) lasers are easily recognized by the cascading scheme, in which electrons traverse a stack of many, typically 30 but sometimes up to 100, active regions alternated with injector regions, rather than only a single active region, as in conventional semiconductor lasers. So far, QC-lasers shared the characteristic, that all stages of the cascade were essentially identical. This makes perfect sense for lasers with optimized performance, with a low threshold current density and high optical output power. The possibility of heterogeneous cascades was sometimes discussed. However, it was uncertain if optimal operating conditions could be achieved for all components of the cascade. Here, we experimentally discuss three types of QC-lasers with heterogeneous cascades. The first type contains two sub-stacks, each using a previously optimized QC structure, connected by a thin InGaAs layer. This results in a QC-laser emitting simultaneously at 5.2 and 8.0 micrometers wavelength, with performance levels similar to those of the respective homogeneous stack lasers. It was not necessary to adjust the design electric field of the two stacks to match each other. Each sub-stack is apportioned the appropriate fraction of the applied bias. In addition, an etch-stop layer inserted between the two sub-stacks allowed fabrication of a tap into the cascade. The latter was used to selectively manipulate the laser threshold of one sub-stack, turning the 8.0 micrometers laser on and off while the adjacent 5.2 micrometers QC-laser was operating undisturbed. We also fabricated a doubly-single mode QC-distributed feedback laser with single-mode emission at 5.0 and 7.5 micrometers with simultaneous single-mode tunability. The second type of QC-laser contains a waveguide core with an interdigitated cascade of two different active regions with matching injectors and emitting at 8.0 and 9.5 micrometers wavelength simultaneously. Finally, the third type of QC-laser with heterogeneous cascade was designed to generate a broadband continuum. We observe gain from 5 to 8 micrometers and laser action continuously from 6 to 8 micrometers .
[1]
E. Gornik,et al.
Analysis of TM-polarized DFB laser structures with metal surface gratings
,
2000,
IEEE Journal of Quantum Electronics.
[2]
F. Capasso.
Band-Gap Engineering: From Physics and Materials to New Semiconductor Devices
,
1987,
Science.
[3]
Federico Capasso,et al.
A multiwavelength semiconductor laser
,
1998,
Nature.
[4]
Federico Capasso,et al.
Threshold reduction in quantum cascade lasers with partially undoped, dual-wavelength interdigitated cascades
,
2002
.
[5]
J. C. Garcia,et al.
Epitaxially stacked lasers with Esaki junctions: A bipolar cascade laser
,
1997
.
[6]
Federico Capasso,et al.
Single-mode tunable, pulsed, and continuous wave quantum-cascade distributed feedback lasers at λ≅4.6-4.7 μm
,
2000
.
[7]
Robert L. Thornton,et al.
Low threshold current dual wavelength planar buried heterostructure lasers with close spatial and large spectral separation
,
1994
.
[8]
F. Capasso,et al.
Quantum cascade lasers with a heterogeneous cascade: Two-wavelength operation
,
2001
.
[9]
Mattias Beck,et al.
Continuous Wave Operation of a Mid-Infrared Semiconductor Laser at Room Temperature
,
2001,
Science.
[10]
C. Sirtori,et al.
Dual-wavelength emission from optically cascaded intersubband transitions.
,
1998,
Optics letters.
[11]
F. Capasso,et al.
New frontiers in quantum cascade lasers and applications
,
2000,
IEEE Journal of Selected Topics in Quantum Electronics.