First Principle Calculation of Accurate Electronic and Related Properties of Zinc Blende Indium Arsenide (zb-InAs)

Diakite, Yacouba Issa; Malozovsky, Yuriy; Bamba, Cheick Oumar; Franklin, Lashounda; Bagayoko, Diola

doi:10.3390/ma15103690

Cited by 8 publications

(2 citation statements)

References 54 publications

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“…2(a). This plane comprises a 7-atom layer of GaSb and a 14-atom layer of InAs, both forming a sphalerite structure characterized by the space group F-43 m 17 . Within the GaSb layer, each gallium atom is tetrahedrally coordinated to four antimony atoms, and vice versa.…”

Section: Simulation Results and Analysismentioning

confidence: 99%

Design of Resonant Cavity-Enhanced InAs/GaSb Superlattice LWIR Photodetector

Gong,

Zhu,

Feng

et al. 2024

Preprint

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Type-II superlattices (T2SLs) have recently emerged as a focal point in long-wavelength infrared (LWIR) detection, showcasing remarkable potential across various applications. In this work, we have revealed a theoretical investigation into the band structure and optical properties of 14/7 ML InAs/GaSb SLs, employing density functional theory (DFT). Our findings show that the energy gap of these SLs is determined to be 0.111 eV through energy band structure analysis by the HSE06 method. Moreover, we have designed a resonant cavity-enhanced "Φ" structure for the 14/7 ML InAs/GaSb SLs infrared detector. This innovative design markedly enhances absorption efficiency, increasing it from 16.48% to an impressive 76.35% at the 11.2 µm wavelength. Further analysis includes a detailed examination of the electric field distribution within this structure and a comprehensive examination of the enhanced plasmonic resonator's perfect absorption phenomenon. The results from these analyses underscore the exceptional absorption capabilities of our resonant cavity-enhanced infrared detector, indicating its potential for significant applications in LWIR SLs focal plane.

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Section: Simulation Results and Analysismentioning

confidence: 99%

Design of Resonant Cavity-Enhanced InAs/GaSb Superlattice LWIR Photodetector

Gong,

Zhu,

Feng

et al. 2024

Preprint

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“…The authors suggest that observed satellites occur as a consequence of a highly anisotropic band structure [41]. The very high anisotropy of heavy-holes in indium arsenide [42] is sometimes referred to "band warping" effect [43][44][45].…”

Section: Mobility Spectra For Series Of P-doped Inas Samplesmentioning

confidence: 99%

InAs light-to-heavy hole effective mass ratio determined experimentally from mobility spectrum analysis

2024

Opto-Electronics Review

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Careful selection of the physical model of the material for a specific doping and selected operating temperatures is a non-trivial task. In numerical simulations that optimize practical devices such as detectors or lasers architecture, this challenge can be very difficult. However, even for such a well-known material as a 5 µm thick layer of indium arsenide on a semiinsulating gallium arsenide substrate, choosing a realistic set of band structure parameters for valence bands is remarkable. Here, the authors test the applicability range of various models of the valence band geometry, using a series of InAs samples with varying levels of p-type doping. Carefully prepared and pretested the van der Pauw geometry samples have been used for magneto-transport data acquisition in the 20-300 K temperature range and magnetic fields up to ±15 T, combined with a mobility spectra analysis. It was shown that in a degenerate statistic regime, temperature trends of mobility for heavy-and light-holes are uncorrelated. It has also been shown that parameters of the valence band effective masses with warping effect inclusion should be used for selected acceptor dopant levels and range of temperatures.

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