Analysis of dark current characteristic of InAs/GaSb superlattice longwave infrared detectors

Junbin Li; Aimin Liu; Zhi Jiang; Jin Yang; Wen Yang; Jincheng Kong; Dongsheng Li; Yanhui Li; Xuchang Zhou

doi:10.3788/IRLA20210399

[1] G A S Halasz, R T Esaki. A new semiconductor superlattice. Appl Phys Lett, 30, 651(1977).

[2] D L Smith, C Mailhiot. Proposal for strained type Ⅱ superlattice infrared detectors. J Appl Phys, 62, 2545(1987).

[3] D R Rhiger. Performance comparison of long-wavelength infrared type Ⅱ superlattice devices with HgCdTe. J Electron Mater, 40, 1815(2011).

[4] C J Hill, A Soibel, S A Keo, et al. Demonstration of large format mid-wavelength infrared focal plane arrays based on superlattice and BIRD detector structures. Infrared Phys Techn, 52, 348(2009).

[5] Nguyen B M, Chen G, Hoang M A, et al. Growth acterization of long wavelength infrared type II superlattice photodiodes on a 3" GaSb wafer[C]Proceedings of SPIE, 2011, 7945: 79451O.

[6] M Walthera, J Schmitza, R Rehma, et al. Growth of InAs/GaSb short-period superlattices for high-resolution mid-wavelength infrared focal plane array detectors. J Cryst Growth, 278, 156(2005).

[7] D Hoffman, B Nguyen, E K Huang, et al. The effect of doping the M-barrier in very long-wave type-II InAs/GaSb heterodiodes. Appl Phys Lett, 93, 031107(2008).

[8] P Manurkar, S Ramezani-Darvish, B M Nguyen, et al. High performance long wavelength infrared mega-pixel focal plane array based on type-II superlattices. Appl Phys Lett, 97, 193505(2010).

[9] S D Gunapala, D Z Ting, J Nguyen, et al. Demonstration of a 1024 × 1024 pixel InAs–GaSb superlattice focal plane array. IEEE Photonics Technol Lett, 22, 1856(2010).

[10] Delaunay P Y, Nosho B Z, Gurga A R,et al. Advances in IIIV based dualb MWIRLWIR FPAs at HRL[C]Proceedings of SPIE,2017, 10177: 101770T.

[11] D Donetsky, S P Svensson, L E Vorobjev, et al. Carrier lifetime measurements in short-period InAs/GaSb strained-layer superlattice structures. Appl Phys Lett, 95, 212104(2009).

[12] B M Nguyen, D Hoffman, P Y Delaunay, et al. Dark current suppression in type II InAs/GaSb superlattice long wavelength infrared photodiodes with M-structure barrier. Appl Phys Lett, 91, 163511(2007).

[13] Klipstein P C, Avnon E, Benny Y, et al. InAsGaSb type II superlattice barrier devices with a low dark current a high quantum efficiency[C]Proceedings of SPIE,2014, 9070: 90700U.

[14] I Vurgaftman, E H Aifer, C L Canedy, et al. Graded band gap for dark-current suppression in long-wave infrared W-structured type-II superlattice photodiodes. Appl Phys Lett, 89, 121114(2006).

[15] A Rogalski, P Martyniuk. InAs/GaInSb superlattices as a promising materialsystem for third generation infrared detectors. Infrared Phys Tech, 48, 39(2006).

[16] J Nguyen, D Z Ting, C J Hill, et al. Dark current analysis of InAs/GaSb superlattices at low temperatures. Infrared Phys Tech, 52, 317(2009).

[17] Sze S M, Kwok K Ng. Physics of semiconduct devices[D]. Wiley: New Jersey, 2006.

[18] V Gopal, E Plis, J B Rodriguez, et al. Modeling of electrical characteristics of midwave type II InAs/GaSb strain layer superlattice diodes. J Appl Phys, 104, 124506(2008).

[19] Q K Yang, F Fuchs, J Schmitz, et al. Investigation of trap-assisted tunneling current in InAs/(GaIn)Sb superlattice long-wavelength photodiodes. Appl Phys Lett, 81, 4757(2002).

[20] W D Hu, X S Chen, Z H Ye, et al. A hybrid surface passivation on HgCdTe long wave infrared detector with in-situ CdTe deposition and high-density hydrogen plasma modification. Appl Phys Lett, 99, 091101(2011).

[21] Kittel C. Introduction to Solid State Physics[M].8th ed. New Yk: Wiley, 2004.

[22] A Rogalski, P Martyniuk, M Kopytko. InAs/GaSb type-II superlattice infrared detectors: Future prospect. Phys Rev Appl, 4, 031304(2017).

CLP Journals