5 research outputs found
Carrier Dynamics in a Tunneling Injection Quantum Dot Semiconductor Optical Amplifier
The process of tunneling injection is known to improve the dynamical
characteristics of quantum well and quantum dot lasers; in the latter, it also
improves the temperature performance. The advantage of the tunneling injection
process stems from the fact that it avoids hot carrier injection, which is a
key performance-limiting factor in all semiconductor lasers. The tunneling
injection process is not fully understood microscopically and therefore it is
difficult to optimize those laser structures. We present here a numerical study
of the broad band carrier dynamics in a tunneling injection quantum dot gain
medium in the form of an optical amplifier operating at 1.55 um. Charge carrier
tunneling occurs in a hybrid state that joins the quantum dot first excited
state and the confined quantum well - injection well states. The hybrid state,
which is placed energetically roughly one LO phonon above the ground state and
has a spectral extent of about 5 meV , dominates the carrier injection to the
ground state. We calculate the dynamical response of the inversion across the
entire gain spectrum following a short pulse perturbation at various
wavelengths and for two bias currents. At a high bias of 200 mA, the entire
spectrum exhibits gain; at 30 mA, the system exhibits a mixed gain - absorption
spectrum. The carrier dynamics in the injection well is calculated
simultaneously. We discuss the role of the pulse excitation wavelengths
relative to the gain spectrum peak and demonstrate that the injection well
responds to all perturbation wavelengths, even those which are far from the
region where the tunneling injection process dominates
Ultra-fast charge carrier dynamics across the spectrum of an optical gain media based on InAs/AlGaInAs/InP quantum dots
The charge carrier dynamics of improved InP-based InAs/AlGaInAs quantum dot (QD) semiconductor optical amplifiers are examined employing the multi-wavelength ultrafast pump-probe measurement technique. The transient transmission response of the continuous wave probe shows interesting dynamical processes during the initial 2-3 ps after the pump pulse, when carriers originating from two photon absorption contribute the least to the recovery. The effects of optical excitations and electrical bias levels on the recovery dynamics of the gain in energetically different QDs are quantified and discussed. The experimental observations are validated qualitatively using a comprehensive finite-difference time-domain model by recording the time evolution of the charge carriers in the QDs ensemble following the pulse