Title :
Single-mode surface plasmon laser
Author :
Tredicucci, A. ; Machl, C. ; Capasso, F. ; Hutchinson, A.L. ; Sivco, D.L. ; Cho, A.Y.
Author_Institution :
Lucent Technol. Bell Labs., Murray Hill, NJ, USA
Abstract :
Summary form only given.The requirement of prohibitively thick dielectric waveguides has so far hindered the development of long wavelength infrared semiconductor lasers. However, optical confinement can take place also at the interface between two materials with dielectric constants of opposite sign. These surface plasmon waves are the basis for a high performance 17 /spl mu/m wavelength laser where light is guided at the interface between the top metal contact and the underlying semiconductor, dramatically reducing the required thicknesses. The concept of distributed feedback (DFB) for surface plasmon propagation is introduced by developing a periodic modulation of the penetration depth in a two-metal grating. Lasing is achieved on a single longitudinal mode with high purity and temperature tuning rates of /spl sim/1 nm/K. We employ a quantum cascade (QC) active material with variable period superlattices.
Keywords :
diffraction gratings; distributed feedback lasers; laser modes; laser tuning; quantum well lasers; surface plasmons; dielectric constants; distributed feedback; high performance 17 /spl mu/m wavelength laser; high purity; laser tuning; optical confinement; quantum cascade active laser material; single longitudinal mode; single-mode surface plasmon laser; surface plasmon propagation; temperature tuning rates; top metal contact; variable period superlattices; Dielectrics; Distributed feedback devices; Optical feedback; Optical surface waves; Optical waveguides; Plasmons; Semiconductor lasers; Semiconductor waveguides; Surface emitting lasers; Waveguide lasers;
Conference_Titel :
Lasers and Electro-Optics, 2000. (CLEO 2000). Conference on
Conference_Location :
San Francisco, CA, USA
Print_ISBN :
1-55752-634-6
DOI :
10.1109/CLEO.2000.906995
