Enhancement of device performance by using quaternary capping over ternary capping in strain-coupled InAs/GaAs quantum dot infrared photodetectors

Tongbram, Binita; Shetty, Saikalash; Ghadi, Hemant; Adhikary, Sourav; Chakrabarti, Subhananda

doi:10.1007/s00339-014-8854-9

Cited by 16 publications

(9 citation statements)

References 26 publications

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“…Strain coupling between vertically spaced QD layers is one such approach that has been found to be particularly effective. , Uncoupled structures of SAQDs form random, small-sized dots with highly inhomogeneous size distribution which on integration into devices leads to undesirable results. In contrast, vertically coupled QDs have a greater dimension and better uniformity due to the propagation of strain from one layer to the next, which also enables them to interact both electronically and mechanically. , In the majority of the cases reported in the literature, vertical coupling of dots has yielded improved characteristics; however, these vertically stacked structures introduce some more shortcomings such as (i) interface roughness, (ii) threaded dislocation in the {111} plane, (iii) vertical threading dislocation, (iv) V-shaped dislocation, (v) poor crystallinity, etc. The close proximity of the dot layers owing to thin intermediate layers results in a high value of cumulative strain propagating in the heterostructures.…”

Section: Introductionmentioning

confidence: 99%

In-Situ Tailoring of Vertically Coupled InAs p-i-p Quantum-Dot Infrared Photodetectors: Toward Homogeneous Dot Size Distribution and Minimization of In–Ga Intermixing

Dongre

Paul

Mondal

et al. 2020

ACS Appl. Electron. Mater.

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The authors report a detailed analysis of an epitaxial growth technique for indium arsenide (InAs) Quantum-dot infrared photodetectors circumvent the detrimental effects arising from the progressively increasing dot-size in vertically coupled heterostructures. Constant overgrowth percentage of the vertically coupled dot-layers has been achieved with the implementation of the growth strategy, which has been validated by cross-sectional transmission electron microscopy (X-TEM) images of the samples. The optical characteristics of these samples have been analyzed through photoluminescence spectroscopy and photoluminescence excitation spectroscopy (PL and PLE) measurements which show longer wavelength response and reduced full width at half-maxima (fwhm) upon implementation of the growth strategy. X-TEM and in-plane and out-of-plane high resolution X-ray diffraction (HR-XRD) measurements suggest morphological improvement upon implementation of the growth strategy, with a reduction in the indium desorption and lowering of defects and dislocation densities. Excellent correlation has been found between the different experimental results and also their theoretical simulations. The fabricated single-pixel photodetectors at low temperature (T = 14 K) show a broad response extending up to the MWIR region (∼4.5 μm) for one of the samples. Also, a strong spectral response in the SWIR region is obtained even at room temperature (T = 300 K). The highest responsivity (R p ) and specific detectivity (D*) values obtained are 166.17 A/W and 8.39 × 10 10 cm Hz 1/2 W −1 at a bias of 5 V and 300 K temperature.

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Section: Introductionmentioning

confidence: 99%

In-Situ Tailoring of Vertically Coupled InAs p-i-p Quantum-Dot Infrared Photodetectors: Toward Homogeneous Dot Size Distribution and Minimization of In–Ga Intermixing

Dongre

Paul

Mondal

et al. 2020

ACS Appl. Electron. Mater.

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“…We have previously investigated the advantages of using quaternary capping over ternary capping in multistacked InAs QDs. 2,4 In addition, Mohanta et al have discussed the benefits of the carrier relaxation process for different spacer layer thicknesses in multistacked InAs QDs. 9 However, the VC structures also have some shortcomings that weaken the QD coupling.…”

Section: Introductionmentioning

confidence: 99%

“…Recently, vertical-coupled (VC) InAs/GaAs quantum dot (QD) heterostructures grown by molecular beam epitaxy (MBE) under the Stranski–Krastanov growth mode have shown a tremendous impact on the performance of optoelectronic devices such as solar cells, lasers, light-emitting diodes, IR detectors, and single-photon emitters. − In addition, the optical, structural, and electrical properties of three-dimensionally confined InAs QDs can be tuned over a wide range by designing various multistacked InAs QD heterostructures with different material compositions. The GaAs spacer layer thickness can also be tailored to achieve the desired emission wavelength .…”

Section: Introductionmentioning

confidence: 99%

“…These uncoupled QD structures degrade the optical quality of InAs/GaAs QD-based devices. Over the past years, extensive research has been carried out to improve the VC stacked structures by methods such as (i) optimizing the GaAs spacer thickness, (ii) introducing a strain-reducing layer, − (iii) varying the material composition of III–V semiconductor alloys of the strain-reducing layer, such as GaAs, InGaAs, , AlGaAs, , InAlGaAs, , GaAsSb, , and InGaAsSb, and (iv) varying the monolayer coverage for the seed-layer InAs QDs in order to achieve a high degree of correlation of vertically aligned QDs with stronger quantum confinement potential. We have previously investigated the advantages of using quaternary capping over ternary capping in multistacked InAs QDs. , In addition, Mohanta et al have discussed the benefits of the carrier relaxation process for different spacer layer thicknesses in multistacked InAs QDs .…”

Section: Introductionmentioning

confidence: 99%

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Impact of an In_xGa_1–xAs Capping Layer in Impeding Indium Desorption from Vertically Coupled InAs/GaAs Quantum Dot Interfaces

Tongbram

Sengupta

Chakrabarti

2018

ACS Appl. Nano Mater.

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This study describes the effect of a thin GaAs spacer of 4.5 nm thickness in a bilayer-coupled InAs quantum dot (QD) heterostructure. Here, we report the first demonstration of InAs/GaAs QDs capped by self-assembled In x Ga1–x As layers. Self-assembled In x Ga1–x As layers were introduced into each intermediate layer across the interface of InAs QDs and the GaAs layer in a vertical-coupled bilayer QD (VCBQD) heterostructure to prevent indium desorption from the QDs. A change in the indium content in the seed-layer InAs QDs changes the self-assembly position and modifies the In x Ga1–x As layer thickness. A theoretical approach was presented to study the formation of self-assembled In x Ga1–x As layers at each strain-free layer. We showed that the strain energy at the second intermediate (ε zz2) layer is greater than that at the first intermediate (ε zz1) layer; ε zz2 depends on the vertical strain channel length. The impact of the In x Ga1–x As layer thickness on the strain energy was studied using high-resolution transmission electron microscopy; a shorter strain channel length was found to facilitate the formation of a more relaxed and larger-sized self-assembled In x Ga1–x As layer in the active layer. This In x Ga1–x As layer formed at the intermediate layer acts as a capping layer or a protective shield for the indium adatoms, preventing their desorption from the InAs QDs. Furthermore, we studied the thermal stability of the self-assembled In x Ga1–x As layer by annealing the VCBQD samples at 700 and 800 °C. This aspect has been investigated for the first time ever in a study of the coupling efficiency between the InAs QDs and In x Ga1–x As capping layer. A high-resolution in-plane (2θχ/ϕ) reciprocal space mapping (RSM) technique provided the connection between the in-plane reciprocal lattice point of the InAs QDs and In x Ga1–x As layers and revealed the strain and coupling between them. InAs QDs fully covered with the self-assembled In x Ga1–x As layer enhanced the photoluminescence intensity by 77% and had an activation energy of 467 meV.

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“…Since intraband transitions in QWs are forbidden for IR light normally incident on a QW slab (parallel to the sensor surface) according to the optical selection rule, QDs are more suited for realizing normal-incidence IR sensors. In particular, the application of InAs/GaAs QDs to QDIPs has been intensively studied [47][48][49][50][51][52][53][54] , because of the well-established growth of self-assembled QDs on GaAs substrates. The reported responsivity range of QDIPs enables detection of mid-wavelength IR (MWIR) light at 3 to 5 µm and long-wavelength IR (LWIR) light at 8 to 12 µm.…”

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confidence: 99%

Infrared photodetector sensitized by InAs quantum dots embedded near an Al0.3Ga0.7As/GaAs heterointerface

Murata

Asahi

Sanguinetti

2020

Sci Rep

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Mid-infrared sensors detect infrared radiation emitted from objects, and are actually widely used for monitoring gases and moisture as well as for imaging objects at or above room temperature. Infrared photodetectors offer fast detection, but many devices cannot provide high responsivity at room temperature. Here we demonstrate infrared sensing with high responsivity at room temperature. The central part of our device is an Al 0.3 Ga 0.7 As/GaAs heterostructure containing inAs quantum-dot (QD) layer with a 10-nm-thick GaAs spacer. In this device, the electrons that have been accumulated at the heterointerface are transferred to the conduction band of the Al 0.3 Ga 0.7 As barrier by absorbing infrared photons and the following drift due to the electric field at the interface. These intraband transitions at the heterointerface are sensitized by the QDs, suggesting that the presence of the QDs increases the strength of the intraband transition near the heterointerface. The room-temperature responsivity spectrum exhibits several peaks in the mid-infrared wavelength region, corresponding to transitions from the inAs QD and wetting layer states as well as the transition from the quantized state of the triangular potential well at the two-dimensional heterointerface. We find that the responsivity is almost independent of the temperature and the maximum value at 295 K is 0.8 A/W at ~ 6.6 µm for a bias of 1 V, where the specific detectivity is 1.8 × 10 10 cmHz 1/2 /W.

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Enhancement of device performance by using quaternary capping over ternary capping in strain-coupled InAs/GaAs quantum dot infrared photodetectors

Cited by 16 publications

References 26 publications

In-Situ Tailoring of Vertically Coupled InAs p-i-p Quantum-Dot Infrared Photodetectors: Toward Homogeneous Dot Size Distribution and Minimization of In–Ga Intermixing

In-Situ Tailoring of Vertically Coupled InAs p-i-p Quantum-Dot Infrared Photodetectors: Toward Homogeneous Dot Size Distribution and Minimization of In–Ga Intermixing

Impact of an In_xGa_1–xAs Capping Layer in Impeding Indium Desorption from Vertically Coupled InAs/GaAs Quantum Dot Interfaces

Infrared photodetector sensitized by InAs quantum dots embedded near an Al0.3Ga0.7As/GaAs heterointerface

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Enhancement of device performance by using quaternary capping over ternary capping in strain-coupled InAs/GaAs quantum dot infrared photodetectors

Cited by 16 publications

References 26 publications

In-Situ Tailoring of Vertically Coupled InAs p-i-p Quantum-Dot Infrared Photodetectors: Toward Homogeneous Dot Size Distribution and Minimization of In–Ga Intermixing

In-Situ Tailoring of Vertically Coupled InAs p-i-p Quantum-Dot Infrared Photodetectors: Toward Homogeneous Dot Size Distribution and Minimization of In–Ga Intermixing

Impact of an InxGa1–xAs Capping Layer in Impeding Indium Desorption from Vertically Coupled InAs/GaAs Quantum Dot Interfaces

Infrared photodetector sensitized by InAs quantum dots embedded near an Al0.3Ga0.7As/GaAs heterointerface

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Impact of an In_xGa_1–xAs Capping Layer in Impeding Indium Desorption from Vertically Coupled InAs/GaAs Quantum Dot Interfaces