Type-II InAs/GaAsSb Quantum Dot Solar Cells With GaAs Interlayer

Kim, Dong‐Young; Hatch, Sabina; Wu, Jiang; Sablon, Kimberly; Lam, Phu; Jurczak, P.; Tang, Mingchu; Gillin, W. P.; Liu, Huiyun

doi:10.1109/jphotov.2018.2815152

Cited by 24 publications

(16 citation statements)

References 29 publications

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“…Using the TEM sample thickness of 60 nm, the QD's areal density in a single QW is 2.1 × 10 10 cm −2 . The determined density for Bi QDs is several times higher than in MOCVD‐grown GaAsBi/GaAs MQW and comparable to other composition QDs in GaAs system (1.26 × 10 10 cm −2 for InAs‐QD/GaAsBi, 4.3 × 10 10 cm −2 for InAs‐QD/GaAsSb, and 2.9 × 10 10 cm −2 for InAs‐QD/GaAs …”

Section: Resultsmentioning

confidence: 99%

HRTEM Study of Size‐Controlled Bi Quantum Dots in Annealed GaAsBi/AlAs Multiple Quantum Well Structure

Skapas

Stanionytė

Paulauskas

et al. 2019

Physica Status Solidi (b)

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High‐resolution transmission electron microscopy (HRTEM) study of statistically large number of Bi quantum dots (QD) in annealed GaAsBi/AlAs multiple quantum well (MQW) structures is presented in this work. Superlattices containing 20 alternating periods of 10 nm thick GaAsBi quantum well and AlAs 20 nm thick barrier layers are grown on semi‐insulating GaAs at 330 °C temperature. Dispersed Bi quantum dots are formed within the bismide layers during a post‐growth annealing at 750 °C. Energy dispersive X‐ray (EDX) mapping and high‐angle annular dark‐field scanning transmission electron microscopy (HAADF‐STEM) analysis reveal that GaAsBi phase is altered during the annealing treatment forming a partially Bi‐depleted GaAsBi phase and semiconducting Bi nanoparticles. AlAs layers are found to act as barriers for Bi out‐diffusion, thus controlling the size of the QDs. The analysis of HRTEM micrographs confirms that Bi quantum dots consist of a rhombohedral Bi phase randomly distributed within zinc blende GaAsBi layers. Geometric phase analysis (GPA) also shows that GaAsBi layers are strained with respect to AlAs layers, as supported by the high‐resolution X‐ray diffraction (HRXRD) data. These findings demonstrate a highly controlled synthesis of Bi‐based quantum dots and pave the way for future applications in the field of infrared devices.

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Section: Resultsmentioning

confidence: 99%

HRTEM Study of Size‐Controlled Bi Quantum Dots in Annealed GaAsBi/AlAs Multiple Quantum Well Structure

Skapas

Stanionytė

Paulauskas

et al. 2019

Physica Status Solidi (b)

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“…3b and hence holes captured in the QW may tunnel through the InAlAs layer making less probable the type II emission. For a thicker In 0.15 Al 0.85 As interlayer (40 Å and 60 Å), the tunneling is further reduced but the electron and hole wavefunction overlap is substantially reduced favoring the recombination of electrons in GaAs with holes in GaAsSb [13]. The optical transition of InAs/GaAsSb QDs can be tailored to the type of application requiring either short or long lifetimes.…”

Section: Resultsmentioning

confidence: 99%

“…The use of InAlAs layers may be of interest to engineering the type of radiative recombination. For type II transition, the insertion of InAlAs will increase the carrier lifetime [13] and the energy separation between the fundamental and first excited states [14–16]. Moreover, the insertion of an InAlAs layer between InAs QDs and GaAsSb is expected to decrease In segregation and suppress In and Ga atoms intermixing between the InAs QDs and the GaAsSb SRL and reduce further the QD strain [17].…”

Section: Introductionmentioning

confidence: 99%

Altering the Optical Properties of GaAsSb-Capped InAs Quantum Dots by Means of InAlAs Interlayers

et al. 2019

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In this work, we investigate the optical properties of InAs quantum dots (QDs) capped with composite In0.15Al0.85As/GaAs0.85Sb0.15 strain-reducing layers (SRLs) by means of high-resolution X-ray diffraction (HRXRD) and photoluminescence (PL) spectroscopy at 77 K. Thin In0.15Al0.85As layers with thickness t = 20 Å, 40 Å, and 60 Å were inserted between the QDs and a 60-Å-thick GaAs0.85Sb0.15 layer. The type II emissions observed for GaAs0.85Sb0.15-capped InAs QDs were suppressed by the insertion of the In0.15Al0.85As interlayer. Moreover, the emission wavelength was blueshifted for t = 20 Å and redshifted for t ≥ 40 Å resulting from the increased confinement potential and increased strain, respectively. The ground state and excited state energy separation is increased reaching 106 meV for t = 60 Å compared to 64 meV for the QDs capped with only GaAsSb SRL. In addition, the use of the In0.15Al0.85As layers narrows significantly the QD spectral linewidth from 52 to 35 meV for the samples with 40- and 60-Å-thick In0.15Al0.85As interlayers.

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“…III-V semiconductor quantum dots (InAs, InGaAs, InP, etc.) formed in self-organized growth mode are typical nanomaterials, widely used in optoelectronic fields like laser, photodetector, LED, and solar cell [5][6][7][8][9]. Lately, InGaAs (InP) surface quantum dots (SQDs) have also attracted much attention in the application field of gas sensing materials [10][11][12].…”

Section: Introductionmentioning

confidence: 99%

Gas Sensitivity of In0.3Ga0.7As Surface QDs Coupled to Multilayer Buried QDs

et al. 2020

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A detailed analysis of the electrical response of In0.3Ga0.7As surface quantum dots (SQDs) coupled to 5-layer buried quantum dots (BQDs) is carried out as a function of ethanol and acetone concentration while temperature-dependent photoluminescence (PL) spectra are also analyzed. The coupling structure is grown by solid source molecular beam epitaxy. Carrier transport from BQDs to SQDs is confirmed by the temperature-dependent PL spectra. The importance of the surface states for the sensing application is once more highlighted. The results show that not only the exposure to the target gas but also the illumination affect the electrical response of the coupling sample strongly. In the ethanol atmosphere and under the illumination, the sheet resistance of the coupling structure decays by 50% while it remains nearly constant for the reference structure with only the 5-layer BQDs but not the SQDs. The strong dependence of the electrical response on the gas concentration makes SQDs very suitable for the development of integrated micrometer-sized gas sensor devices.

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Type-II InAs/GaAsSb Quantum Dot Solar Cells With GaAs Interlayer

Cited by 24 publications

References 29 publications

HRTEM Study of Size‐Controlled Bi Quantum Dots in Annealed GaAsBi/AlAs Multiple Quantum Well Structure

HRTEM Study of Size‐Controlled Bi Quantum Dots in Annealed GaAsBi/AlAs Multiple Quantum Well Structure

Altering the Optical Properties of GaAsSb-Capped InAs Quantum Dots by Means of InAlAs Interlayers

Gas Sensitivity of In0.3Ga0.7As Surface QDs Coupled to Multilayer Buried QDs

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