InAs/GaSb type-II superlattice infrared detectors: three decades of development

Recently, there has been considerable progress towards III-V antimonide-based low dimensional solids development and device design innovations. From a physics point of view, the type-II InAs/GaSb superlattice is an extremely attractive proposition. Their development results from two primary motivations: the perceived challenges of reproducibly fabricating high-operability HgCdTe FPAs at reasonable cost and theoretical predictions of lower Auger recombination for type-II superlattice (T2SL) detectors compared to HgCdTe. Lower Auger recombination should be translated into a fundamental advantage for T2SL over HgCdTe in terms of lower dark current and/or higher operating temperature, provided other parameters such as Shockley-Read-Hall lifetime are equal. Based on these promising results it is obvious now that the InAs/GaSb superlattice technology is competing with HgCdTe third generation detector technology with the potential advantage of standard III-V technology to be more competitive in costs and as a consequence series production pricing. Comments to the statement whether the superlattice IR photodetectors can outperform the “bulk” narrow gap HgCdTe detectors is one of the most important questions for the future of IR photodetectors presented by Rogalski at the April 2006 SPIE meeting in Orlando, Florida, are more credible today and are presented in this paper. It concerns the trade-offs between two most competing IR material technologies: InAs/GaSb type-II superlattices and HgCdTe ternary alloy system.

[1]  Majid Zandian,et al.  MBE HgCdTe Technology: A Very General Solution to IR Detection, Described by “Rule 07”, a Very Convenient Heuristic , 2008 .

[2]  Kim Beech,et al.  1024 x 1024 LWIR SLS FPAs: status and characterization , 2012, Defense + Commercial Sensing.

[3]  Leon Shterengas,et al.  Interband absorption strength in long-wave infrared type-II superlattices with small and large superlattice periods compared to bulk materials , 2016 .

[4]  Krishnamurthy Mahalingam,et al.  Electrical, Optical and Structural Studies of INAS/INGASB VLWIR Superlattices , 2013 .

[5]  Darryl L. Smith,et al.  Proposal for strained type II superlattice infrared detectors , 1987 .

[6]  Steve Grossman,et al.  k·p model for the energy dispersions and absorption spectra of InAs/GaSb type-II superlattices , 2012 .

[7]  Frank Rutz,et al.  Dual-Color InAs/GaSb Superlattice Focal-Plane Array Technology , 2011 .

[8]  Steve Grossman,et al.  InAs/GaSb Type II superlattice barrier devices with a low dark current and a high-quantum efficiency , 2014, Defense + Security Symposium.

[9]  M. Carmody,et al.  High-Operating Temperature HgCdTe: A Vision for the Near Future , 2016, Journal of Electronic Materials.

[10]  Małgorzata Kopytko,et al.  Simplified model of dislocations as a SRH recombination channel in the HgCdTe heterostructures , 2012 .

[11]  Michael A. Kinch An infrared journey , 2015, Defense + Security Symposium.

[12]  Alexander Soibel,et al.  Type-II Superlattice Infrared Detectors , 2011 .

[13]  Steve Grossman,et al.  Modeling InAs/GaSb and InAs/InAsSb Superlattice Infrared Detectors , 2014, Journal of Electronic Materials.

[14]  John F. Klem,et al.  Effects of layer thickness and alloy composition on carrier lifetimes in mid-wave infrared InAs/InAsSb superlattices , 2014 .

[15]  Joseph G. Pellegrino,et al.  HOT MWIR HgCdTe performance on CZT and alternative substrates , 2012, Defense + Commercial Sensing.

[16]  Jerry R. Meyer,et al.  AUGER LIFETIME ENHANCEMENT IN INAS-GA1-XINXSB SUPERLATTICES , 1994 .

[17]  Waldemar Gawron,et al.  Investigation of trap levels in HgCdTe IR detectors through low frequency noise spectroscopy , 2016 .

[18]  L. Esaki,et al.  A new semiconductor superlattice , 1977 .

[19]  N. Snapi,et al.  Low SWaP MWIR detector based on XBn focal plane array , 2013, Defense, Security, and Sensing.

[20]  A Kinch Michael,et al.  State-of-the-Art Infrared Detector Technology , 2014 .

[21]  Shun Lien Chuang,et al.  Direct observation of minority carrier lifetime improvement in InAs/GaSb type-II superlattice photodiodes via interfacial layer control , 2013 .

[22]  Leo Esaki,et al.  Observation of semiconductor‐semimetal transition in InAs‐GaSb superlattices , 1979 .

[23]  Manijeh Razeghi,et al.  High performance long wavelength infrared mega-pixel focal plane array based on type-II superlattices , 2010 .

[24]  L. Langof,et al.  Type II superlattice technology for LWIR detectors , 2016, SPIE Defense + Security.

[25]  David R. Rhiger,et al.  Performance Comparison of Long-Wavelength Infrared Type II Superlattice Devices with HgCdTe , 2011 .

[26]  M. Šindelářová,et al.  Hoshmand, A.R.: Statistical Methods for Environmental and Agricultural Sciences. Second Edition. - CRC Press, Boca Raton , 2001, Biologia Plantarum.

[27]  Amy W. K. Liu,et al.  Significantly improved minority carrier lifetime observed in a long-wavelength infrared III-V type-II superlattice comprised of InAs/InAsSb , 2011 .

[28]  A. Rogalski Infrared Detectors, Second Edition , 2010 .

[29]  P. K. Liao,et al.  Minority carrier lifetime in p-HgCdTe , 2005 .

[30]  S D Gunapala,et al.  Demonstration of a 1024 $\times$ 1024 Pixel InAs–GaSb Superlattice Focal Plane Array , 2010, IEEE Photonics Technology Letters.

[31]  Thomas H. Myers,et al.  InSb: A Key Material for IR Detector Applications , 1986 .