Title :
Hot carrier relaxation in quantum well structures using Monte Carlo simulation
Author :
Cassan, Eric ; Galdin, S. ; Dollfus, P. ; Musseau, O. ; Hesto, P.
Author_Institution :
Inst. d´´Electron. Fondamentale, Univ. de Paris-Sud, Orsay, France
Abstract :
The relaxation process of high energy electrons, generated in the active layer of an ungraded separate-confinement heterostructure single quantum well laser diode by a radiative perturbation, is studied. Capture and escape are treated as mixed scattering events in a Monte Carlo simulation. The overlap integral between unconfined and confined states, used in the calculation of mixed scattering rates, is given. The beginning of the thermalization is very similar to the one in bulk material, but the weakness of the capture rate is responsible for a carrier bottleneck at the top of the well. The overall relaxation time appears very sensitive to detailed structure parameters, as the well thickness and the optical confinement layer width
Keywords :
Monte Carlo methods; carrier relaxation time; hot carriers; laser theory; quantum well lasers; Monte Carlo simulation; capture rate; carrier bottleneck; confined states; escape rate; hot carrier relaxation time; mixed scattering rate; optical confinement layer; overlap integral; radiative perturbation; separate confinement heterostructure single quantum well laser diode; thermalization; Carrier confinement; Diode lasers; Electrons; High speed optical techniques; Hot carriers; Laser modes; Lasers and electrooptics; Optical scattering; Particle scattering; Quantum well lasers;
Conference_Titel :
Radiation and Its Effects on Components and Systems, 1997. RADECS 97. Fourth European Conference on
Conference_Location :
Cannes
Print_ISBN :
0-7803-4071-X
DOI :
10.1109/RADECS.1997.698853
