Title :
Transport solutions for the SCH quantum-well laser diode
Author :
Taylor, G.W. ; Claisse, P.R.
Author_Institution :
Dept. of Electr. & Syst. Eng., Connecticut Univ., Storrs, CT, USA
fDate :
12/1/1995 12:00:00 AM
Abstract :
The current-voltage relations for the barrier regions in the SCH quantum well laser diode are derived in general terms under the assumption of charge neutrality. The boundary conditions are established at the quantum well SCH region interface by the clamping of the Fermi levels in the quantum well above threshold. It is shown that the current flow is comprised of opposing drift and diffusion flows with drift slightly in excess of diffusion. The recombination current in the SCH region has contributions from both drift and diffusion mechanisms. Expressions are also derived to determine the resistance and capacitance associated with the SCH transport. The appropriate small-signal current versus small-signal Fermi level dependence is specified for application to the small-signal laser response formulation
Keywords :
Fermi level; capacitance; carrier lifetime; electron-hole recombination; laser theory; quantum well lasers; Fermi level clamping; SCH quantum-well laser diode; SCH transport; barrier regions; boundary conditions; capacitance; charge neutrality; current flow; current-voltage relations; diffusion flows; drift; quantum well SCH region interface; recombination current; resistance; small-signal Fermi level dependence; small-signal current; small-signal laser response formulation; threshold; transport solutions; Boundary conditions; Charge carrier density; Charge carrier processes; Clamps; Diode lasers; Equations; Frequency response; Laser modes; Quantum well lasers; Radiative recombination; Steady-state;
Journal_Title :
Quantum Electronics, IEEE Journal of
