Title :
Theory of the strain-symmetrized silicon-based Ge-Si superlattice laser
Author :
Friedman, Lionel ; Soref, Richard A. ; Sun, Gregory ; Lu, Yanwu
Author_Institution :
Sensors Directorate, Air Force Res. Lab., Hanscom AFB, MA, USA
Abstract :
A unipolar p-i-p silicon-based intersubband laser consisting of a symmetrically strained GeSi superlattice on a relaxed Si0.5Ge 0.5 buffer layer is modeled and analyzed. The strain-symmetrization removes the limitation on the size of the superlattice. The procedure for calculating the in-plane energy dispersion is extended to a superlattice. Analysis of the in-plane energy dispersion shows that the population inversion is local-in-k-space. For an 11 ML/11 ML superlattice (15.4 Å/15.4 Å), interminiband lasing between HH2 and HH1 is predicted at λ=2.2 μm. From the envelope functions and material properties, the miniband lifetimes and laser gain are calculated. For a current density of 10 kA/cm2, a gain of GL=96/cm is calculated. Alternate structures with larger expected gains are considered. Quantum-parallel, quantum-cascade, and quantum-staircase lasing are examined
Keywords :
Ge-Si alloys; current density; dispersion relations; laser theory; laser transitions; population inversion; quantum well lasers; radiative lifetimes; semiconductor device models; semiconductor superlattices; symmetry; 2.2 mum; GeSi; current density; envelope functions; in-plane energy dispersion; interminiband lasing; laser gain; local-in-k-space; material properties; miniband lifetimes; population inversion; quantum-cascade lasers; quantum-parallel lasers; quantum-staircase lasing; relaxed Si0.5Ge0.5 buffer layer; semiconductor superlattices; strain-symmetrization; strain-symmetrized silicon-based Ge-Si superlattice laser; symmetrically strained Ge-Si superlattice; unipolar p-i-p silicon-based intersubband laser; Buffer layers; Capacitive sensors; Current density; Laser modes; Laser theory; Material properties; Semiconductor lasers; Semiconductor superlattices; Sun; Tensile strain;
Journal_Title :
Selected Topics in Quantum Electronics, IEEE Journal of
DOI :
10.1109/2944.736106
