Title :
Tapered active-region quantum cascade lasers (λ = 4.8 μm) for virtual suppression of carrier-leakage currents
Author :
Kirch, J.D. ; Shin, Jae Cheol ; Chang, Chung-Ching ; Mawst, L.J. ; Botez, D. ; Earles, T.
Author_Institution :
ECE Dept., Univ. of Wisconsin-Madison, Madison, WI, USA
Abstract :
A new deep-well quantum-cascade laser (QCL) design, for which the barrier layers in the active region are tapered such that their conduction band edges increase in energy from the injection barrier to the exit barrier, results in significant suppression of the carrier leakage in 4.8 μm-emitting devices. For heatsink temperatures in the 20-60°C range, the characteristic temperature coefficients for threshold, T0, and slope efficiency, T1, reach values as high as 231 K and 797 K, respectively. The T1 values are more than a factor of two higher than the best reported values for high-performance, 4.6-4.9 μm -emitting QCLs of similar injector-doping level. At 20°C, the threshold-current density for uncoated, 30-period, 3-mm-long devices is only ~1.55 kA/cm2.
Keywords :
conduction bands; current density; doping profiles; heat sinks; laser beams; leakage currents; quantum cascade lasers; μm-emitting QCLs; barrier layer; carrier-leakage current virtual suppression; conduction band edge; deep-well quantum-cascade laser design; emitting device; heatsink temperature; injection barrier; injector-doping level; slope efficiency; tapered active-region quantum cascade laser; temperature 20 degC to 60 degC; temperature coefficient; threshold-current density; wavelength 4.6 mum to 4.9 mum; wavelength 4.8 mum;
Journal_Title :
Electronics Letters
DOI :
10.1049/el.2012.0017
