Effect of an additional infrared excitation on the luminescence efficiency of a single InAs/GaAs quantum dot

Moskalenko, E. S.; Donchev, V.; Karlsson, K. F.; Holtz, Per-Olof; Ḿonemar, B.; Schoenfeld, Winston V.; Garcı́a, J.M.; Petroff, P. M.

doi:10.1103/physrevb.68.155317

Cited by 38 publications

(56 citation statements)

References 49 publications

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“…For larger C-doping densities, the QD occupancy increases more slowly with increasing n A , while at the same time the depletion length rapidly decreases below it maximum value. For the typical acceptor densities of the order of 10 13 − 10 14 cm −3 [58], the QD is nearly populated by three holes, which is more than the two holes occupancy considered in our work hypothesis (see section IV A). However, excepting an average value of the typical acceptor densities, we do not have a precise knowledge of the C-doping in the QD vicinity.…”

Section: Discussionmentioning

confidence: 89%

Photoneutralization and slow capture of carriers in quantum dots probed by resonant excitation spectroscopy

et al. 2013

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We investigate experimentally and theoretically the resonant emission of single InAs/GaAs quantum dots in a planar microcavity. Due to the presence of at least one residual charge in the quantum dots, the resonant excitation of the neutral exciton is blocked. The influence of the residual doping on the initial quantum dots charge state is analyzed, and the resonant emission quenching is interpreted as a Coulomb blockade effect. The use of an additional non-resonant laser in a specific low power regime leads to the carrier draining in quantum dots and allows an efficient optical gating of the exciton resonant emission. A detailed population evolution model, developed to describe the carrier draining and the optical gate effect, perfectly fits the experimental results in the steady state and dynamical regimes of the optical gate with a single set of parameters. We deduce that ultra-slow Auger-and phonon-assisted capture processes govern the carrier draining in quantum dots with relaxation times in the 1 -100 µs range. We conclude that the optical gate acts as a very sensitive probe of the quantum dots population relaxation in an unprecedented slow-capture regime.

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Section: Discussionmentioning

confidence: 89%

Photoneutralization and slow capture of carriers in quantum dots probed by resonant excitation spectroscopy

et al. 2013

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“…The distance between the dots is consequently smaller than the diffusion length of the photoinduced carriers. Our previous study revealed an exciton diffusion length in the WL of approximately 1 m. 7 Since only a very limited WL contribution can be observed in the low-temperature PL spectrum, we roughly estimate a dot separation of about 1 m and a dot density of approximately 10 8 cm −2 .…”

Section: Resultsmentioning

confidence: 99%

“…Our previous work based on lateral electric field dependence studies on single dot related PL indicates a depth of the potential fluctuations of approximately 3 meV. 14 Furthermore, PLE measurements reveal a Stokes shift of about 5 meV, 7,15 which also gives a rough estimate of the depth of the local WL potential fluctuations. Based on these different experimental observations, the depth of the WL potential fluctuations is estimated to be 3 -5 meV.…”

Section: Figmentioning

confidence: 99%

Magnetic field effects on optical and transport properties inInAs∕GaAsquantum dots

et al. 2006

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A photoluminescence study of self-assembled InAs/ GaAs quantum dots under the influence of magnetic fields perpendicular and parallel to the dot layer is presented. At low temperatures, the magnetic field perpendicular to the dot layer alters the in-plane transport properties due to localization of carriers in wetting layer ͑WL͒ potential fluctuations. Decreased transport in the WL results in a reduced capture into the quantum dots and consequently a weakened dot-related emission. The effect of the magnetic field exhibits a considerable dot density dependence, which confirms the correlation to the in-plane transport properties. An interesting effect is observed at temperatures above approximately 100 K, for which magnetic fields, both perpendicular and parallel to the dot layer, induced an increment of the quantum dot photoluminescence. This effect is ascribed to the magnetic confinement of the exciton wave function, which increases the probability for carrier capture and localization in the dot, but affects also the radiative recombination with a reduced radiative lifetime in the dots under magnetic compression.

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“…11,12 In contrast to single laser excitation, which only results in X 0 , when adding a second infrared ͑IR͒ laser excitation X + is formed, as was demonstrated by us earlier. 13 An even higher polarization is measured for X + , c =73%, which is considered to be an upper bound for spin polarization of electrons captured into the QD from the wetting layer ͑WL͒.…”

Section: Manipulating the Spin Polarization Of Excitons In A Single Qmentioning

confidence: 99%

“…Detailed descriptions of the sample and of the experimental setup are given elsewhere. [11][12][13] c was determined as c = ͑I co − I cross ͒ / ͑I co + I cross ͒, where I co ͑I cross ͒ corresponds to the spectrally integrated PL signal of the co͑cross-͒circular components.…”

Section: Manipulating the Spin Polarization Of Excitons In A Single Qmentioning

confidence: 99%

Manipulating the spin polarization of excitons in a single quantum dot by optical means

Larsson

Moskalenko

Holtz

2011

Applied Physics Letters

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Circular polarization studies of photoluminescence from the neutral (X0) and the positively charged (X+) excitons are reported for individual InAs/GaAs quantum dots (QDs). High polarization degrees, 60% for X0 and 73% for X+, were recorded without any external magnetic field applied. These studies show that the QD polarization and population dynamics are controllable either by varying the photoexcitation intensity or by using a second IR laser excitation.

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Effect of an additional infrared excitation on the luminescence efficiency of a single InAs/GaAs quantum dot

Cited by 38 publications

References 49 publications

Photoneutralization and slow capture of carriers in quantum dots probed by resonant excitation spectroscopy

Photoneutralization and slow capture of carriers in quantum dots probed by resonant excitation spectroscopy

Magnetic field effects on optical and transport properties inInAs∕GaAsquantum dots

Manipulating the spin polarization of excitons in a single quantum dot by optical means

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