Quantum dot strain engineering of InAs∕InGaAs nanostructures

Seravalli, L.; Minelli, M.; Frigeri, P.; Franchi, S.; Guizzetti, G.; Patrini, M.; Ciabattoni, T.; Geddo, M.

doi:10.1063/1.2424523

Cited by 83 publications

(80 citation statements)

References 59 publications

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“…Metamorphic QDs allow single photon emission in the telecom windows; moreover, by engineering strain and band discontinuities, as proposed in Ref. 21, these nanostructures may have the potential for tuning emission and other single QD properties. …”

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confidence: 99%

“…In structures with x = 0.30 LCL the emission is redshifted, due to reduction in QD strain and of QD-CL band discontinuities. 21 Thus, metamorphic nanostructures are able to emit one single photon into the second telecommunication window band ͑1.3 m͒ and the emission wavelength may be tuned by changing the composition of the LCL layers. Figure 2͑a͒ shows the power excitation dependence PL from the x = 0.15 sample.…”

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confidence: 99%

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Single quantum dot emission at telecom wavelengths from metamorphic InAs/InGaAs nanostructures grown on GaAs substrates

Seravalli

Trevisi

Frigeri

et al. 2011

Applied Physics Letters

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We report on the growth by molecular beam epitaxy and the study by atomic force microscopy and photoluminescence of low density metamorphic InAs/InGaAs quantum dots. subcritical InAs coverages allow to obtain 10 8 cm −2 dot density and metamorphic In x Ga 1−x As ͑x = 0.15, 0.30͒ confining layers result in emission wavelengths at 1.3 m. We discuss optimal growth parameters and demonstrate single quantum dot emission up to 1350 nm at low temperatures, by distinguishing the main exciton complexes in these nanostructures. Reported results indicate that metamorphic quantum dots could be valuable candidates as single photon sources for long wavelength telecom windows.

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confidence: 99%

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confidence: 99%

Single quantum dot emission at telecom wavelengths from metamorphic InAs/InGaAs nanostructures grown on GaAs substrates

Seravalli

Trevisi

Frigeri

et al. 2011

Applied Physics Letters

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“…Single QD emission in the long wavelength range in these structures has been demonstrated by us in reference [7]. The use of metamorphic InGaAs layer allows for the red-shift of the emission wavelength, thanks to the reduction of strain of QDs and band discontinuities [17], while the deposition of a subcritical coverage of InAs followed by annealing allows to obtain very low QD density (1 x 10 8 cm -2 ) for structures grown on metamorphic layers [18]. and XX 0 transitions, and the larger value for X + with respect to X 0 can be justified by a random carrier capture mechanism, as previously demonstrated for InAs single QDs emitting at 900-1000 nm [19], [7] In this way, continuous lines at the inset of figure 1.c represent the best fit to the measured integrated intensity variation by using a random population model [19].…”

Section: Samples and Experimental Set-upmentioning

confidence: 99%

Time resolved emission at 1.3 μm of a single InAs quantum dot by using a tunable fibre Bragg grating

et al. 2013

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Photoluminescence and time resolved photoluminescence from single metamorphic InAs/GaAs quantum dots (QDs) emitting at 1.3 μm have been measured by means of a novel fibre-based characterization set-up. We demonstrate that the use of a wavelength tunable Fibre Bragg Grating (FBG) filter increases the light collection efficiency by more than one order of magnitude as compared to a conventional grating monochromator. We identified single charged exciton and neutral biexciton transitions on the framework of a random population model. The QD recombination dynamics under pulsed excitation can be understood under the weak quantum confinement potential limit and the interaction between carriers at the Wetting Layer (WL) and QD states. 68.65.La, 78.47.jd, 42.79.Ci, Introduction: PACS:

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“…The QD effective recombination rate (r i ) is composed by the sum of radiative and non-radiative terms. The QD radiative recombination rate is obtained from the inverse of the measured PL decay time at 10 K. The activation energy of the thermal carrier capture into defect states has been set to $20 meV, 25,26 The main output parameter is the energy dependent i values plotted in Figure 7(a). We observe how i decreases with the QD size in both samples with almost the same trend, reflecting the carrier escape character.…”

Section: A Thermal Escapementioning

confidence: 99%

“…It has been investigated attending to the available final states, i.e., QD excited states, 15,21 wetting layer, 4,6,7,13,20,22 GaAs barrier, 8,9,23 and impurity/defect levels. [23][24][25][26] Thermal escape can be also investigated attending to the nature of the particles being promoted to a higher energy state. 14 Depending on the model, the correlated (excitonic escape), 6,8,10,12,23 the uncorrelated electron-hole pair (ambipolar escape), 4,9,14 or just one of the carriers (unipolar escape) 15 can be considered.…”

Section: Introductionmentioning

confidence: 99%

Size dependent carrier thermal escape and transfer in bimodally distributed self assembled InAs/GaAs quantum dots

Muñoz‐Matutano

Suárez²,

Canet‐Ferrer

et al. 2012

Journal of Applied Physics

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We have investigated the temperature dependent recombination dynamics in two bimodally distributed InAs self assembled quantum dots samples. A rate equations model has been implemented to investigate the thermally activated carrier escape mechanism which changes from exciton-like to uncorrelated electron and hole pairs as the quantum dot size varies. For the smaller dots, we find a hot exciton thermal escape process. We evaluated the thermal transfer process between quantum dots by the quantum dot density and carrier escape properties of both samples.

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Quantum dot strain engineering of InAs∕InGaAs nanostructures

Cited by 83 publications

References 59 publications

Single quantum dot emission at telecom wavelengths from metamorphic InAs/InGaAs nanostructures grown on GaAs substrates

Single quantum dot emission at telecom wavelengths from metamorphic InAs/InGaAs nanostructures grown on GaAs substrates

Time resolved emission at 1.3 μm of a single InAs quantum dot by using a tunable fibre Bragg grating

Size dependent carrier thermal escape and transfer in bimodally distributed self assembled InAs/GaAs quantum dots

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