Title :
Theoretical Modeling of Relative Intensity Noise in p-Doped 1.3-μm InAs/GaAs Quantum Dot Lasers
Author :
Sanaee, Maryam ; Zarifkar, A.
Author_Institution :
Dept. of Commun. & Electron., Shiraz Univ., Shiraz, Iran
Abstract :
Theoretical analysis of relative intensity noise (RIN) characteristics of p-doped QD lasers has been presented. By considering dynamics of electrons and holes separately at GaAs barrier, wetting layer (WL), and three discrete QDs levels, 12 rate equations have been linearized in presence of the Langevin noise sources. Calculations indicate that RIN level of QD laser reduces slightly through p-doping. Although providing excess holes to WL state decreases the shot noise, resulted from quantum confined levels and photon noise, the shot noise originated from three and two dimensional carrier densities, respectively, inside the barrier and WL states, increases. It is shown that the RIN level declines in p-doped QD lasers by increasing the injection current, which is in agreement with a recent experimental report. It is also demonstrated that the RIN level of QD lasers decreases by increasing the number of QD layers, and a shot noise plays the main role in this reduction.
Keywords :
III-V semiconductors; carrier density; gallium arsenide; indium compounds; laser noise; quantum dot lasers; shot noise; wetting; InAs-GaAs; Langevin noise sources; electron dynamics; hole dynamics; injection current; p-doped QD lasers; p-doped quantum dot lasers; photon noise; quantum confined levels; rate equations; relative intensity noise characteristics; shot noise; theoretical modeling; three-dimensional carrier density; two-dimensional carrier density; wavelength 1.3 mum; wetting layer; Equations; Gallium arsenide; Laser noise; Laser theory; Mathematical model; Photonics; Langevin noise sources; Nonlinear gain; QD lasers; nonlinear gain; p-doping; relative intensity noise;
Journal_Title :
Lightwave Technology, Journal of
DOI :
10.1109/JLT.2014.2376186
