Photoluminescence of InAs1−xSbx/AlSb single quantum wells: Transition from type-II to type-I band alignment

Yang, M. J.; Bennett, B. R.; Fatemi, M.; Lin‐Chung, P. J.; Moore, W. J.; Yanɡ, Chao

doi:10.1063/1.373517

Cited by 15 publications

(6 citation statements)

References 22 publications

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“…That is why the transition to the type II junction should occur for Sb content in the solid solution less than 12%, in contrast to the value of 15% predicted in the paper. 11 It should be noted that the EL intensity of sample A was 2-3 times higher than one of the sample B, which indicates better structural parameters probably due to the lower strain in the structure.…”

Section: Resultsmentioning

confidence: 84%

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Two-band superlinear electroluminescence in GaSb based nanoheterostructures with AlSb/InAs1−x Sbx/AlSb deep quantum well

Mikhaĭlova¹,

Иванов²,

Danilov³

et al. 2014

Journal of Applied Physics

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Section: Resultsmentioning

confidence: 84%

“…Sample A exhibits better structural parameters. According to the paper, 11 the transition from type II to type I for AlSb/InAsSb is at 15% Sb content in the solid state phase. Fig.…”

mentioning

confidence: 99%

Two-band superlinear electroluminescence in GaSb based nanoheterostructures with AlSb/InAs1−x Sbx/AlSb deep quantum well

Mikhaĭlova¹,

Иванов²,

Danilov³

et al. 2014

Journal of Applied Physics

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“…A heavy doping was applied on the ohmic contact region of InAs cap layer in order to reduce the contact resistant [18]. A Schottky contact forms between the gate metal electrode and the InAlAs protection layer [19], to prevent the electrons continually spreading to the metal. Controlling the gate bias voltage can change the Schottky barrier, thus controlling the 2DEG density in channel.…”

Section: Simulation and Principle Analysismentioning

confidence: 99%

Channel Characteristics of InAs/AlSb Heterojunction Epitaxy: Comparative Study on Epitaxies with Different Thickness of InAs Channel and AlSb Upper Barrier

et al. 2019

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Because of the high electron mobility and electron velocity in the channel, InAs/AlSb high electron mobility transistors (HEMTs) have excellent physical properties, compared with the other traditional III-V semiconductor components, such as ultra-high cut-off frequency, very low power consumption and good noise performance. In this paper, both the structure and working principle of InAs/AlSb HEMTs were studied, the energy band distribution of the InAs/AlSb heterojunction epitaxy was analyzed, and the generation mechanism and scattering mechanism of two-dimensional electron gas (2DEG) in InAs channel were demonstrated, based on the software simulation in detail. In order to discuss the impact of different epitaxial structures on the 2DEG and electron mobility in channel, four kinds of epitaxies with different thickness of InAs channel and AlSb upper-barrier were manufactured. The samples were evaluated with the contact Hall test. It is found the sample with a channel thickness of 15 nm and upper-barrier layer of 17 nm shows a best compromised sheet carrier concentration of 2.56 × 1012 cm−2 and electron mobility of 1.81 × 104 cm2/V·s, and a low sheet resistivity of 135 Ω/□, which we considered to be the optimized thickness of channel layer and upper-barrier layer. This study is a reference to further design InAs/AlSb HEMT, by ensuring a good device performance.

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“…In this paper, we propose a material design of AlSb/InAsSb heterostructures with an InAs 1– x Sb x alloy composition corresponding to x = 0.2 that is latticed matched to AlSb and x = 0.6 which has the narrowest bandgap and smallest effective mass . Owing to the small effective mass and narrow bandgap, InAsSb alloy is expected to have a higher electron mobility, along with its higher 2DEG concentration for intersubband scattering and type‐I band alignment with AlSb to confine both electrons and holes, making it superior for HEMT applications than AlSb/InAs heterostructures . To test the potential advantage that AlSb/InAsSb heterostructures could achieve, we employ the improved theoretical model of self‐consistent calculation of Schrödinger–Poisson equations by taking into account the strain effect and the nonparabolicity effect.…”

Section: Introductionmentioning

confidence: 99%

Self‐consistent analysis of InAsSb quantum‐well heterostructures

Zhang

Guan

et al. 2014

Physica Status Solidi (b)

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Based on our self-consistent calculation of the Schrödinger-Poisson equation by taking into consideration both the strain effect and the nonparabolicity effect, we propose a material design for InAsSb-based quantum-well heterostructures. A twodimensional electron gas concentration exceeding 3 Â 10 12 cm À2 could be achieved within AlSb/InAs 0.4 Sb 0.6 heterostructures without the occurrence of intersubband scattering, higher than that in AlSb/InAs heterostructures. Our InAsSb-based quantumwell heterostructure is proved to be advantageous for applications as high electron mobility transistors.

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Photoluminescence of InAs1−xSbx/AlSb single quantum wells: Transition from type-II to type-I band alignment

Cited by 15 publications

References 22 publications

Two-band superlinear electroluminescence in GaSb based nanoheterostructures with AlSb/InAs1−x Sbx/AlSb deep quantum well

Two-band superlinear electroluminescence in GaSb based nanoheterostructures with AlSb/InAs1−x Sbx/AlSb deep quantum well

Channel Characteristics of InAs/AlSb Heterojunction Epitaxy: Comparative Study on Epitaxies with Different Thickness of InAs Channel and AlSb Upper Barrier

Self‐consistent analysis of InAsSb quantum‐well heterostructures

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