dc.description.abstract |
Infrared (210 m) is an extremely useful region of the electromagnetic spectrum
for trace gas analysis in environmental or medical monitoring applications, since
a large number of strong fundamental vibrational molecular transition spectral
lines fall in this range. Present work explores the mid-IR photodetection mechanism
in III-V quantum con ned system in twofold ways. Firstly, it models the
extent of spectral linewidth broadening of photo-detector. Secondly, it investigates
whether a strong perturbation of light can modulate the electronic bandstructure
and thus add non-linearity to the opto-electronic behavior of the device. Electronphoton
interaction in the device is modeled in Non-equillibrium Green's Function(
NEGF) formalism. Photo-absorption mechanism in the detector is correlated
to reduced carrier lifetime in ground state which leads to uncertainty in energy
levels and homogeneous spectral widening- which is calculated here. Besides homogeneous
broadening in photo-current spectrum, inhomogeneous broadening in
quantum dot-in-a-well infrared photo-detector(DWELL-IP) is also taken care of.
Inhomogeneous broadening is attributed to the non-uniform size and composition
of quantum dots in a self-grown assembly. Individual contribution of these factors
towards spectral broadening is modeled in order to get the envelop of photocurrent
spectrum. The model generates photocurrent spectrum with 1:4 m broadening
centered at 3:5 m at 77K for a DWELL-IP, which agrees with the experimental
result. The calculated photocurrent spectral width of 1:3 m for GaAs=AlGaAs
Quantum Well(QW) centered at 8:31 m at 77K also supports experimental data.
In addition to photocurrent peak at mid-IR, the calculation reveals the emergence
of a second resonant peak in the spectrum of QW-IP in far infrared region
(20 50 m) as the photon volume density increases upto 0:1% of carrier density
inside the active region. At such high density of photon, perturbation theory falls
short of explaining the system behavior. To account for the creation of far-IR resonant
photocurrent peak, a hybrid density-of-states for strongly coupled electronphoton
system is introduced here. The mid-IR photocurrent peak is found to shift
upto 2 m towards the red end as the photon volume density reaches from 0:1% to
1:0% of carrier density, while the far-IR peak experiences pronounced blue-shift. |
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