Generation–recombination reduction in InAsSb photodiodes

Carras, Mathieu; Renard, Christian; Marcadet, X.; Reverchon, Jean-Luc; Vinter, B.; Berger, V.

doi:10.1088/0268-1242/21/12/037

Cited by 12 publications

(10 citation statements)

References 14 publications

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“…The room-temperature R 0 A products (Table 1) of the devices with a wider bandgap InPSb barrier layer show some improvement over the InAsSb homojunction devices. These values are comparable to the previously reported data [11,12] for InAsSb photodetectors with AlInAsSb barrier layers. The dependence of the room-temperature zero-bias resistance of InPSb/InAsSb diodes on device size is plotted in Fig.…”

Section: Resultssupporting

confidence: 91%

Growth of InAsSb/InPSb heterojunctions for mid-IR detector applications

Pitts

David

Cherng

et al. 2008

Journal of Crystal Growth

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Section: Resultssupporting

confidence: 91%

Growth of InAsSb/InPSb heterojunctions for mid-IR detector applications

Pitts

David

Cherng

et al. 2008

Journal of Crystal Growth

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“…The growth of InAsSb based detectors has been reported recently by several groups using molecular beam epitaxy. [14,15] In the present work, mesa diode structures were fabricated consisting of a top p-type contact layer of either InAsSb or InPSb (~10 17 cm -3 ), following by an non intentionally doped (nid) 1µm absorption layer of InAsSb grown on an n + GaSb substrate. Typically measurements were performed via top side contacts placed on the mesa (p-contact) or on the exposed n + GaSb substrate (ncontact).…”

Section: Device Resultsmentioning

confidence: 99%

InAsSb and InPSb materials for mid infrared photodetectors

David

Pitts

Martine

et al. 2010

2010 22nd International Conference on Indium Phosphide and Related Materials (IPRM)

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III-V semiconductor materials are under active investigation for use as optical detectors in the mid infrared wavelength region from 3 to 12 µm. In this paper we summarize recent progress on the development of III-V materials for this application based on the material InAsSb. We first present the results of investigations in the use of strained balanced type II superlattices of InAsSb/InAs to extend the absorption wavelength of this material system beyond the limits of the maximum InAsSb bulk value. We present results on the growth of InPSb heterojunction structures with the aim of reducing thermal diffusion current and surface leakage. Finally we present some preliminary device results indicating the promise of this material system.

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“…The external upconversion efficiency was measured to be 0.06 W/W at 2.85 µm. Further study on improving the InAsSb photodetector structures is under way and is expected to minimize the Shockley-Read Hall (SRH) recombination centers [5] in the middle of the band gap and thus achieve higher temperature and higher efficiency operation. a2888_1.pdf…”

Section: Summerymentioning

confidence: 99%

“…The addition of As to the InSb compound material, yielding InAsSb ternary, slightly increases the band gap and consequently decreases the maximum detectable wavelength to below 5 µm. Nevertheless, the detector maintains the same excellent detectivity of an InSb infrared photodetector at much higher temperatures [4]- [5], which are attainable through a thermal-electrical cooler. This enhancement will have profound impacts on the thermal imaging devices in the 3-5 µm range for high performance, easy implementation and low cost thermal imaging camera.…”

mentioning

confidence: 99%

Mid-infrared optical upconversion by integrating an InAsSb photodetector with a GaAs light emitting diode

Boucherif

Ban

Luo

et al. 2007

2007 Conference on Lasers and Electro-Optics (CLEO)

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We report the fabrication and experimental results of a midinfrared optical up-converter that was fabricated using wafer fusion technology. Midinfrared optical upconversion from 4.0 to 0.84 µm was demonstrated at temperatures up to 200 K. Introduction:Thermal imaging in the range of 3 to 5 µm wavelength has became increasingly important due to the large number of applications for military and civilian purposes [1] such as military and police target detection and acquisition, predictive maintenance (early failure warning) on mechanical and electrical equipment, and pollution effluent detection. The standard procedure for fabricating InSb-based focal plane arrays for thermal imaging is based on indium bump technology. However this "one-piece-at-a time" process limits the yield and scalability of this technique. An alternative method to implement a thermal imaging camera is to integrate monolithically a photodetector and a light emitting diode (LED) to form an optical upconverter [2]. By using such a mid-infared (MIR) to near-infrared (NIR) optical upconverter, in combination with a commerciallyavailable Si CCDs camera, MIR detection and large-area MIR imaging functionality can be achieved. In a previous study some of the present authors have successfully demonstrated upconversion operation in the range of 3-5 µm based on InSb photodiode and GaAs/AlGaAs LED [3], but the device works only at cryogenic temperatures, which requires expensive, bulky, power-hungry and time-consuming cooler to operate. These factors limit the applications of the InSb-based upconverters. The addition of As to the InSb compound material, yielding InAsSb ternary, slightly increases the band gap and consequently decreases the maximum detectable wavelength to below 5 µm. Nevertheless, the detector maintains the same excellent detectivity of an InSb infrared photodetector at much higher temperatures [4]- [5], which are attainable through a thermal-electrical cooler. This enhancement will have profound impacts on the thermal imaging devices in the 3-5 µm range for high performance, easy implementation and low cost thermal imaging camera. In this work, we proposed and demonstrated a wafer-fused MIR optical upconverter that consists of an InAsSb photodiode and a GaAs LED. The external upconversion efficiency was measured to be 0.06 W/W at 200 K.

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Generation–recombination reduction in InAsSb photodiodes

Cited by 12 publications

References 14 publications

Growth of InAsSb/InPSb heterojunctions for mid-IR detector applications

Growth of InAsSb/InPSb heterojunctions for mid-IR detector applications

InAsSb and InPSb materials for mid infrared photodetectors

Mid-infrared optical upconversion by integrating an InAsSb photodetector with a GaAs light emitting diode

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