Temperature dependence of photoluminescence spectra in InAs/GaAs quantum dot superlattices with large thicknesses

Dai, Yu‐Tzu; Fan, Jung-Chuan; Chen, Y. F.; Lin, Ray-Ming; Lee, S. C.; Lin, Hao‐Hsiung

doi:10.1063/1.366255

Cited by 120 publications

(42 citation statements)

References 14 publications

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“…The InAs QD PL intensity quenching is usually attributed to thermal escape of carriers from the QDs to the wetting layer (WL) or to the GaAs barrier with following recombination via non-radiative (NR) centers [4,5]. In DWELL structures the introduction of surrounding QWs changes the height of potential barriers for exciton thermal escape from QDs and can increase the density of NR centers.…”

Section: Introductionmentioning

confidence: 99%

Exciton thermal escape in symmetric InAs quantum dots in InGaAs/GaAs well structures

Espínola

Torchynska

Polupan

et al. 2007

Phys. Status Solidi (c)

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The photoluminescence and its temperature dependence have been investigated for the ensembles of InAs quantum dots embedded in symmetric In 0.15 Ga 0.85 As/GaAs quantum wells with different PL intensities. The solution of the set of rate equations for exciton dynamics was used to analyze the nature of thermal activation energies of the QD photoluminescence quenching. It is revealed two different stages of thermally activated quenching of the QD PL intensity caused by thermal escape of excitons from the In 0.15 Ga 0.85 As/GaAs QW into the GaAs barrier and from the QDs into the QWs with their subsequent nonradiative recombination. The variety of activation energies of PL thermal quenching is discussed as well.

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Section: Introductionmentioning

confidence: 99%

Exciton thermal escape in symmetric InAs quantum dots in InGaAs/GaAs well structures

Espínola

Torchynska

Polupan

et al. 2007

Phys. Status Solidi (c)

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“…It is clear from the formula (6), that in high quality QD structures (#2, #3 and #4) with low concentrations of the NR1 and NR2 centres the PL intensity I(T) is linearly dependent on excitation power (or generation rates, G InGaAs , G GaAs ), as it is demonstrated in Fig.5. In low quality QD structures (#1 and #5) photo-generated excitons recombine partially via NR1 and NR2 centres and W (T) changes Sublineary versus power (Fig.5).…”

Section: Discussion Of Pl Integrated Intensity Dependences Versus Temmentioning

confidence: 85%

“…PL intensity decay in InAs QDs as a rule attributed to thermal escape of carriers from QDs into the wetting layer or into the GaAs barrier [5][6][7][8], as well as to thermally activated capture of excitons by nonradiative defects in the GaAs barrier or at the GaAs/InAs interface [5,9,10]. The unusual variations of emission energy and the full width at half maximum (FWHM) of PL bands in the InAs/GaAs self-assembled QDs have been investigated earlier as well [11,12].…”

Section: Introductionmentioning

confidence: 99%

“…In these systems, the strong localization of an electronic wave function leads to an atomic-like electronic density of states and permits to realize the novel and improved photonic and electronic devices. Microlectronic and optoelectronic devices based on quantum wells (QWs) with InAs QDs have been the subject of investigation for the applications in semiconductor lasers for the optical fiber communication [1][2][3], infrared photo-detectors [4][5][6], electronic memory devices [7,8], as well as single electron devices and single photon light sources on the base of single-QD structures for the quantum information applications [9][10][11][12]. QDs are especially attractive for the applications in semiconductor lasers.…”

Section: Introductionmentioning

confidence: 99%

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InAs Quantum Dots in Symmetric InGaAs/GaAs Quantum Wells

Torchynska¹

2012

Fingerprints in the Optical and Transport Properties of Quantum Dots

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“…The size and hence emis− sion wavelength can be tuned by changing the growth con− ditions [7]. It has been shown that an increase in the InAs monolayer coverage leads to larger dots [8]. But increasing the monolayer coverage beyond 3 ML leads to other prob− lems such as coalescing of islands causing large non−unifor− mities in dot size [9].…”

Section: Introductionmentioning

confidence: 99%

A novel approach to increase emission wavelength of InAs/GaAs quantum dots by using a quaternary capping layer

Chowdhury

Adhikary

Halder

et al. 2010

Opto-Electronics Review

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In this paper, we present a new approach to obtain large size dots in an MBE grown InAs/GaAs multilayer quantum dot system. This is achieved by adding an InAlGaAs quaternary capping layer in addition to a high growth temperature (590°C) GaAs capping layer with the view to tune the emission wavelength of these QDs towards the 1.3 μm/0.95 eV region important for communication devices. Strain driven migration of In atoms from InAlGaAs alloy to the InAs QDs effectively increases the size of QDs. Microscopic investigations were carried out to study the dot size and morphology in the different layers of the grown samples. Methods to reduce structural defects like threading dislocations in multilayer quantum dot samples are also studied.

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Temperature dependence of photoluminescence spectra in InAs/GaAs quantum dot superlattices with large thicknesses

Cited by 120 publications

References 14 publications

Exciton thermal escape in symmetric InAs quantum dots in InGaAs/GaAs well structures

Exciton thermal escape in symmetric InAs quantum dots in InGaAs/GaAs well structures

InAs Quantum Dots in Symmetric InGaAs/GaAs Quantum Wells

A novel approach to increase emission wavelength of InAs/GaAs quantum dots by using a quaternary capping layer

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