Author_Institution :
Bellcore, Red Bank, NJ, USA
Abstract :
Recent progress in the development of the concept and technology of semiconductor quantum wire (QWR) lasers is reviewed. In these quasi-one-dimensional structures, optical gain is provided by charge carriers that are quantum mechanically confined in two dimensions within wire-like active regions. These devices are expected to exhibit improved laser performance, including extremely low threshold currents (in the μA range), higher modulation bandwidth, narrower spectral linewidth, and reduced temperature sensitivity. QWR lasers would thus be particularly useful in applications involving densely packed laser arrays and monolithic integration of lasers with low-power electronics, including computer optical interconnects, optical computing, and integrated optoelectronic circuits. Approaches for fabricating these novel structures are reviewed, and recent successful demonstrations of lasing in semiconductor QWRs are described. Prospects for further progress in this area are also discussed
Keywords :
integrated optoelectronics; optical information processing; optical interconnections; optical modulation; semiconductor junction lasers; semiconductor laser arrays; semiconductor quantum wires; QWR lasers; charge carriers; computer optical interconnects; densely packed laser arrays; integrated optoelectronic circuits; laser performance; modulation bandwidth; monolithic integration; optical computing; optical gain; quasi-one-dimensional structures; semiconductor lasers; semiconductor quantum wire; spectral linewidth; temperature sensitivity; threshold currents; wire-like active regions; Carrier confinement; Charge carriers; Optical arrays; Optical computing; Optical modulation; Optical sensors; Quantum mechanics; Semiconductor laser arrays; Semiconductor lasers; Wire;
