Effects of layer thickness and alloy composition on carrier lifetimes in mid-wave infrared InAs/InAsSb superlattices

Aytac, Yigit; Olson, B. V.; Kim, J. K.; Shaner, Eric A.; Hawkins, Samuel D.; Klem, John F.; Flatté, Michael E.; Boggess, Thomas F.

doi:10.1063/1.4890578

Cited by 64 publications

(37 citation statements)

References 28 publications

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“…Samples are grown by molecular beam epitaxy using previously described techniques [6,9,10,13]. For all seven samples, the epitaxial layers consist of a GaSb buffer layer, a bottom 100-nm Al(As,Sb) barrier layer, an unintentionally doped and nominally 4-μm-thick T2SL absorber layer, a top 100-nm Al(As,Sb) barrier layer, and a 150-nm In(As,Sb) cap layer.…”

Section: Resultsmentioning

confidence: 99%

“…Temperature-and carrier-density-dependent studies on MWIR InAs=InðAs; SbÞ T2SLs have shown that SRH recombination limits the MC carrier lifetime at low temperatures and low-injection carrier densities [5,6,[8][9][10]13]. The mid-band-gap SRH recombination centers identified in MWIR InAs=InðAs; SbÞ T2SLs have been previously reported to be at an energy approximately 250 meV below the valence-band edge of bulk GaSb [5,9].…”

Section: Introductionmentioning

confidence: 97%

“…InAs=InðAs; SbÞ type-II superlattices (T2SLs) were proposed as an alternative material to Hg(Cd,Te) for infrared (IR) detection in 1985 [1]. Since then, many different designs and growth methods have been studied to improve the structural and optical properties of these T2SLs to realize next-generation IR detectors and focal plane arrays [2][3][4][5][6][7][8][9][10][11]. Improvements in detectivity and responsivity have been the main focus of T2SL photodetector development; however Hg(Cd,Te) continues to set the goals for dark current and sensitivity [12].…”

Section: Introductionmentioning

confidence: 99%

“…Improvements in detectivity and responsivity have been the main focus of T2SL photodetector development; however Hg(Cd,Te) continues to set the goals for dark current and sensitivity [12]. Improvements in T2SL detector performance depend critically on the minority-carrier (MC) lifetime, which currently is controlled by flaw-related Shockley-Read-Hall (SRH) recombination [5,6,[8][9][10]13] at typical operating temperatures. Previously, InAs=InðAs; SbÞ T2SLs have been shown to have MC lifetimes of approximately 10 μs in the midwave infrared (MWIR) [6,13] and hundreds of nanoseconds in the long-wave infrared (LWIR) [14,15], with Auger coefficients reported between 1 and 5 × 10 −26 cm 6 =s for MWIR [6,10] and low 10 −25 cm 6 =s for LWIR [15].…”

Section: Introductionmentioning

confidence: 99%

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Evidence of a Shockley-Read-Hall Defect State Independent of Band-Edge Energy inInAs/In(As,Sb)Type-II Superlattices

et al. 2016

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A set of seven InAs=InðAs; SbÞ type-II superlattices (T2SLs) are designed to have specific band-gap energies between 290 meV (4.3 μm) and 135 meV (9.2 μm) in order to study the effects of the T2SL bandgap energy on the minority-carrier lifetime. A temperature-dependent optical pump-probe technique is used to measure the carrier lifetimes, and the effect of a midgap defect level on the carrier-recombination dynamics is reported. The Shockley-Read-Hall (SRH) defect state is found to be at energy of approximately −250 AE 12 meV relative to the valence-band edge of bulk GaSb for the entire set of T2SL structures, even though the T2SL valence-band edge shifts by 155 meV on the same scale. These results indicate that the SRH defect state in InAs=InðAs; SbÞ T2SLs is singular and is nearly independent of the exact position of the T2SL band-gap or band-edge energies. They also suggest the possibility of engineering the T2SL structure such that the SRH state is removed completely from the band gap, a result that should significantly increase the minority-carrier lifetime.

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Section: Resultsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 97%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Evidence of a Shockley-Read-Hall Defect State Independent of Band-Edge Energy inInAs/In(As,Sb)Type-II Superlattices

et al. 2016

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“…A fast, transient increase in differential-transmission signal is observed with a measured response time of 1.4 ps and 2 ps for 2.4 µm and 3.2 µm probe wavelengths, respectively. These timescales characterize the rate at which pump-induced hot carriers thermalize and relax to the band edge 20 . When the probe wavelength continues to increase, the differentialtransmission signal becomes progressively slower, and when the probe wavelength is extended to 4 µm, just above the bandgap, the Pauli-blocking transient persists for nearly 90 ps.…”

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confidence: 99%

Probing the free-carrier absorption in multi-layer black phosphorus

Aytac

Mittendorff

Murphy

2018

Applied Physics Letters

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We study the carrier relaxation dynamics in thin black phosphorus (bP) using time-resolved differential transmission measurements. The inter-band and intra-band transitions, relaxation, and carrier recombination lifetimes are revealed by tuning the mid-infrared probe wavelength above and below the bandgap of black phosphorus. When the probe energy exceeds the bandgap, Pauli blocked inter-band transitions are observed. The differential transmission signal changes sign from positive to negative when the probe energy is below the bandgap, due to the absence of inter-band transitions and enhancement in the free-carrier absorption (FCA). The minority carrier lifetime and radiative recombination coefficient are estimated 1.3 ns, and 5.9×10 −10 cm 3 /s, respectively. The overall recombination lifetime of bP is limited by radiative recombination for excess carrier densities larger than 5×10 19 cm −3 .

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Emerging Type‐II Superlattices of InAs/InAsSb and InAs/GaSb for Mid‐Wavelength Infrared Photodetectors

Alshahrani

Kesaria

Anyebe

et al. 2021

Advanced Photonics Research

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Mid‐wavelength infrared (MWIR) photodetectors (PDs) are highly essential for environmental sensing of hazardous gases, security, defense, and medical applications. Mercury cadmium telluride (MCT) materials have been the most used detector in the MWIR range. However, it is plagued by several challenges including toxicity concerns, a high rate of Auger nonradiative recombination, a large band‐to‐band (BTB) tunneling current, nonuniformity, and the need for cryogenic cooling. Theoretically, it is predicted that type‐II superlattice (T2SL) materials can emerge as an alternative with the potential to outperform the current state‐of‐the‐art MCT PDs due to suppression of Auger recombination associated with bandgap engineering and reduced BTB tunneling current caused by the larger effective mass. Based on this theoretical prediction, it is believed that T2SL have the potential to operate at high temperatures and overcome the size, weight, and power consumption limitations of MCT. Herein, a detailed review of the fundamental material properties of T2SL PDs is provided while providing a comparison of the optical and electrical performances of Ga‐free (InAs/InAsSb) and Ga‐based (InAs/GaSb) T2SL PDs. Finally, recent advances in IR detection technologies including focal plane arrays and quantum cascade infrared photodetectors are explored.

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Effects of layer thickness and alloy composition on carrier lifetimes in mid-wave infrared InAs/InAsSb superlattices

Cited by 64 publications

References 28 publications

Evidence of a Shockley-Read-Hall Defect State Independent of Band-Edge Energy inInAs/In(As,Sb)Type-II Superlattices

Evidence of a Shockley-Read-Hall Defect State Independent of Band-Edge Energy inInAs/In(As,Sb)Type-II Superlattices

Probing the free-carrier absorption in multi-layer black phosphorus

Emerging Type‐II Superlattices of InAs/InAsSb and InAs/GaSb for Mid‐Wavelength Infrared Photodetectors

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