Title :
Phonon-pumped SiGe-Si interminiband terahertz laser
Author :
Sun, Gregory ; Soref, Richard A. ; Khurgin, Jacob B.
Author_Institution :
Dept. of Phys., Massachusetts Univ., Boston, MA, USA
Abstract :
The first phonon-pumped semiconductor laser has been proposed and theoretically investigated. The active region is an unbiased boron-doped Si0.94Ge0.06-Si superlattice with Si0.97Ge0.03 buffer layers embedded in a surface-plasmon strip waveguide. Warm and cool heat sinks create a temperature gradient across the waveguide. A heat buffer layer adjacent to the cool sink reflects optical phonons and transmits acoustic phonons, Within the resonator, the difference in effective temperatures of optical and acoustic phonons provides hole pumping for the lasing transition between the heavy-hole 2 (HH2) and heavy-hole 1 (HH1) minibands. A gain of 280/cm at the 5 THz emission frequency is predicted for 6×1017/cm3 doping at temperatures of 300 K and 77 K for optical and acoustic phonons, respectively. A range of operating conditions in phonon-pumped IV-IV, III-V, and II-VI materials appears feasible
Keywords :
Ge-Si alloys; boron; heat sinks; optical pumping; phonons; semiconductor lasers; semiconductor superlattices; silicon; 300 K; 77 K; II-VI materials; Si0.94Ge0.06-Si:B; Si0.97Ge0.03; Si0.97Ge0.03 buffer layers; acoustic phonons; active region; cool heat sinks; effective temperatures; emission frequency; heat buffer layer; heavy-hole 1 minibands; heavy-hole 2 minibands; hole pumping; lasing transition; optical phonons; phonon-pumped; phonon-pumped SiGe-Si interminiband terahertz laser; phonon-pumped semiconductor laser; surface-plasmon strip waveguide; unbiased boron-doped Si0.94Ge0.06/Si superlattice; warm heat sinks; Acoustic emission; Laser theory; Optical buffering; Optical pumping; Optical resonators; Optical superlattices; Optical waveguides; Phonons; Stimulated emission; Temperature;
Journal_Title :
Selected Topics in Quantum Electronics, IEEE Journal of
DOI :
10.1109/2944.954153
