Type II superlattice technology for LWIR detectors

P. C. Klipstein; E. Avnon; D. Azulai; Y. Benny; R. Fraenkel; A. Glozman; E. Hojman; O. Klin; L. Krasovitsky; L. Langof; I. Lukomsky; M. Nitzani; I. Shtrichman; N. Rappaport; N. Snapi; E. Weiss; A. Tuito

doi:10.1117/12.2222776

Type II superlattice technology for LWIR detectors

P. C. Klipstein, E. Avnon, D. Azulai, Y. Benny, R. Fraenkel, A. Glozman, E. Hojman, O. Klin, L. Krasovitsky, L. Langof, I. Lukomsky, M. Nitzani, I. Shtrichman, N. Rappaport, N. Snapi, E. Weiss, A. Tuito

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution › peer-review

52 Scopus citations

Abstract

SCD has developed a range of advanced infrared detectors based on III-V semiconductor heterostructures grown on GaSb. The XBn/XBp family of barrier detectors enables diffusion limited dark currents, comparable with MCT Rule-07, and high quantum efficiencies. This work describes some of the technical challenges that were overcome, and the ultimate performance that was finally achieved, for SCD's new 15 μm pitch "Pelican-D LW" type II superlattice (T2SL) XBp array detector. This detector is the first of SCD's line of high performance two dimensional arrays working in the LWIR spectral range, and was designed with a ∼9.3 micron cut-off wavelength and a format of 640 x 512 pixels. It contains InAs/GaSb and InAs/AlSb T2SLs, engineered using k • p modeling of the energy bands and photo-response. The wafers are grown by molecular beam epitaxy and are fabricated into Focal Plane Array (FPA) detectors using standard FPA processes, including wet and dry etching, indium bump hybridization, under-fill, and back-side polishing. The FPA has a quantum efficiency of nearly 50%, and operates at 77 K and F/2.7 with background limited performance. The pixel operability of the FPA is above 99% and it exhibits a stable residual non uniformity (RNU) of better than 0.04% of the dynamic range. The FPA uses a new digital read-out integrated circuit (ROIC), and the complete detector closely follows the interfaces of SCD's MWIR Pelican-D detector. The Pelican-D LW detector is now in the final stages of qualification and transfer to production, with first prototypes already integrated into new electro-optical systems.

Original language	English
Title of host publication	Infrared Technology and Applications XLII
Editors	Paul R. Norton, Charles M. Hanson, Gabor F. Fulop, Bjorn F. Andresen
Publisher	SPIE
ISBN (Electronic)	9781510600607
DOIs	https://doi.org/10.1117/12.2222776
State	Published - 2016
Externally published	Yes
Event	Infrared Technology and Applications XLII - Baltimore, United States Duration: 18 Apr 2016 → 21 Apr 2016

Publication series

Name	Proceedings of SPIE - The International Society for Optical Engineering
Volume	9819
ISSN (Print)	0277-786X
ISSN (Electronic)	1996-756X

Conference

Conference	Infrared Technology and Applications XLII
Country/Territory	United States
City	Baltimore
Period	18/04/16 → 21/04/16

Bibliographical note

Publisher Copyright:
© 2016 SPIE.

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10.1117/12.2222776

Cite this

Klipstein, P. C., Avnon, E., Azulai, D., Benny, Y., Fraenkel, R., Glozman, A., Hojman, E., Klin, O., Krasovitsky, L., Langof, L., Lukomsky, I., Nitzani, M., Shtrichman, I., Rappaport, N., Snapi, N., Weiss, E., & Tuito, A. (2016). Type II superlattice technology for LWIR detectors. In P. R. Norton, C. M. Hanson, G. F. Fulop, & B. F. Andresen (Eds.), Infrared Technology and Applications XLII Article 98190T (Proceedings of SPIE - The International Society for Optical Engineering; Vol. 9819). SPIE. https://doi.org/10.1117/12.2222776

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title = "Type II superlattice technology for LWIR detectors",

abstract = "SCD has developed a range of advanced infrared detectors based on III-V semiconductor heterostructures grown on GaSb. The XBn/XBp family of barrier detectors enables diffusion limited dark currents, comparable with MCT Rule-07, and high quantum efficiencies. This work describes some of the technical challenges that were overcome, and the ultimate performance that was finally achieved, for SCD's new 15 μm pitch {"}Pelican-D LW{"} type II superlattice (T2SL) XBp array detector. This detector is the first of SCD's line of high performance two dimensional arrays working in the LWIR spectral range, and was designed with a ∼9.3 micron cut-off wavelength and a format of 640 x 512 pixels. It contains InAs/GaSb and InAs/AlSb T2SLs, engineered using k • p modeling of the energy bands and photo-response. The wafers are grown by molecular beam epitaxy and are fabricated into Focal Plane Array (FPA) detectors using standard FPA processes, including wet and dry etching, indium bump hybridization, under-fill, and back-side polishing. The FPA has a quantum efficiency of nearly 50%, and operates at 77 K and F/2.7 with background limited performance. The pixel operability of the FPA is above 99% and it exhibits a stable residual non uniformity (RNU) of better than 0.04% of the dynamic range. The FPA uses a new digital read-out integrated circuit (ROIC), and the complete detector closely follows the interfaces of SCD's MWIR Pelican-D detector. The Pelican-D LW detector is now in the final stages of qualification and transfer to production, with first prototypes already integrated into new electro-optical systems.",

author = "Klipstein, {P. C.} and E. Avnon and D. Azulai and Y. Benny and R. Fraenkel and A. Glozman and E. Hojman and O. Klin and L. Krasovitsky and L. Langof and I. Lukomsky and M. Nitzani and I. Shtrichman and N. Rappaport and N. Snapi and E. Weiss and A. Tuito",

note = "Publisher Copyright: {\textcopyright} 2016 SPIE.; Infrared Technology and Applications XLII ; Conference date: 18-04-2016 Through 21-04-2016",

year = "2016",

doi = "10.1117/12.2222776",

language = "אנגלית",

series = "Proceedings of SPIE - The International Society for Optical Engineering",

publisher = "SPIE",

editor = "Norton, {Paul R.} and Hanson, {Charles M.} and Fulop, {Gabor F.} and Andresen, {Bjorn F.}",

booktitle = "Infrared Technology and Applications XLII",

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Klipstein, PC, Avnon, E, Azulai, D, Benny, Y, Fraenkel, R, Glozman, A, Hojman, E, Klin, O, Krasovitsky, L, Langof, L, Lukomsky, I, Nitzani, M, Shtrichman, I, Rappaport, N, Snapi, N, Weiss, E & Tuito, A 2016, Type II superlattice technology for LWIR detectors. in PR Norton, CM Hanson, GF Fulop & BF Andresen (eds), Infrared Technology and Applications XLII., 98190T, Proceedings of SPIE - The International Society for Optical Engineering, vol. 9819, SPIE, Infrared Technology and Applications XLII, Baltimore, United States, 18/04/16. https://doi.org/10.1117/12.2222776

Type II superlattice technology for LWIR detectors. / Klipstein, P. C.; Avnon, E.; Azulai, D. et al.
Infrared Technology and Applications XLII. ed. / Paul R. Norton; Charles M. Hanson; Gabor F. Fulop; Bjorn F. Andresen. SPIE, 2016. 98190T (Proceedings of SPIE - The International Society for Optical Engineering; Vol. 9819).

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution › peer-review

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AU - Avnon, E.

AU - Azulai, D.

AU - Benny, Y.

AU - Fraenkel, R.

AU - Glozman, A.

AU - Hojman, E.

AU - Klin, O.

AU - Krasovitsky, L.

AU - Langof, L.

AU - Lukomsky, I.

AU - Nitzani, M.

AU - Shtrichman, I.

AU - Rappaport, N.

AU - Snapi, N.

AU - Weiss, E.

AU - Tuito, A.

PY - 2016

Y1 - 2016

N2 - SCD has developed a range of advanced infrared detectors based on III-V semiconductor heterostructures grown on GaSb. The XBn/XBp family of barrier detectors enables diffusion limited dark currents, comparable with MCT Rule-07, and high quantum efficiencies. This work describes some of the technical challenges that were overcome, and the ultimate performance that was finally achieved, for SCD's new 15 μm pitch "Pelican-D LW" type II superlattice (T2SL) XBp array detector. This detector is the first of SCD's line of high performance two dimensional arrays working in the LWIR spectral range, and was designed with a ∼9.3 micron cut-off wavelength and a format of 640 x 512 pixels. It contains InAs/GaSb and InAs/AlSb T2SLs, engineered using k • p modeling of the energy bands and photo-response. The wafers are grown by molecular beam epitaxy and are fabricated into Focal Plane Array (FPA) detectors using standard FPA processes, including wet and dry etching, indium bump hybridization, under-fill, and back-side polishing. The FPA has a quantum efficiency of nearly 50%, and operates at 77 K and F/2.7 with background limited performance. The pixel operability of the FPA is above 99% and it exhibits a stable residual non uniformity (RNU) of better than 0.04% of the dynamic range. The FPA uses a new digital read-out integrated circuit (ROIC), and the complete detector closely follows the interfaces of SCD's MWIR Pelican-D detector. The Pelican-D LW detector is now in the final stages of qualification and transfer to production, with first prototypes already integrated into new electro-optical systems.

AB - SCD has developed a range of advanced infrared detectors based on III-V semiconductor heterostructures grown on GaSb. The XBn/XBp family of barrier detectors enables diffusion limited dark currents, comparable with MCT Rule-07, and high quantum efficiencies. This work describes some of the technical challenges that were overcome, and the ultimate performance that was finally achieved, for SCD's new 15 μm pitch "Pelican-D LW" type II superlattice (T2SL) XBp array detector. This detector is the first of SCD's line of high performance two dimensional arrays working in the LWIR spectral range, and was designed with a ∼9.3 micron cut-off wavelength and a format of 640 x 512 pixels. It contains InAs/GaSb and InAs/AlSb T2SLs, engineered using k • p modeling of the energy bands and photo-response. The wafers are grown by molecular beam epitaxy and are fabricated into Focal Plane Array (FPA) detectors using standard FPA processes, including wet and dry etching, indium bump hybridization, under-fill, and back-side polishing. The FPA has a quantum efficiency of nearly 50%, and operates at 77 K and F/2.7 with background limited performance. The pixel operability of the FPA is above 99% and it exhibits a stable residual non uniformity (RNU) of better than 0.04% of the dynamic range. The FPA uses a new digital read-out integrated circuit (ROIC), and the complete detector closely follows the interfaces of SCD's MWIR Pelican-D detector. The Pelican-D LW detector is now in the final stages of qualification and transfer to production, with first prototypes already integrated into new electro-optical systems.

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A2 - Fulop, Gabor F.

A2 - Andresen, Bjorn F.

PB - SPIE

T2 - Infrared Technology and Applications XLII

Y2 - 18 April 2016 through 21 April 2016

ER -

Type II superlattice technology for LWIR detectors

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