Fast Response Hot (111) HGCDTE MWIR Detectors

Grodecki, K.; Martyniuk, P.; Kopytko, M.; Kowalewski, A.; Stępień, D.; Kębłowski, A.; Piotrowski, A.; Piotrowski, J.; Gawron, W.; Rogalski, A.

doi:10.1515/mms-2017-0044

Artykuł - szczegóły

Tytuł artykułu

Fast Response Hot (111) HGCDTE MWIR Detectors

Autorzy

Grodecki K. , Martyniuk P. , Kopytko M. , Kowalewski A. , Stępień D. , Kębłowski A. , Piotrowski A. , Piotrowski J. , Gawron W. , Rogalski A.

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DOI

10.1515/mms-2017-0044

Warianty tytułu

Języki publikacji

Abstrakty

In this work we report simulation and experimental results for an MWIR HgCdTe photodetector designed by computer simulation and fabricated in a joint laboratory run by VIGO Sytems S.A. and Military University of Technology. The device is based on a modified N⁺pP⁺ heterostructure grown on 2”., epiready, semi-insulating (100) GaAs substrates in a horizontal MOCVD AIX 200 reactor. The devices were examined by measurements of spectral and time responses as a function of a bias voltage and operating temperatures. The time response was measured with an Optical Parametric Oscillator (OPO) as the source of ~25 ps pulses of infrared radiation, tuneable in a 1.55–16 μm spectral range. Two-stage Peltier cooled devices (230 K) with a 4.1 μm cut-off wavelength were characterized by 1.6 × 10¹² cm Hz^1/2/W peak detectivity and < 1 ns time constant for V > 500 mV.

Słowa kluczowe

HgCdTe MWIR photodetector response time

Wydawca

Komitet Metrologii i Aparatury Naukowej PAN

Czasopismo

Metrology and Measurement Systems

Rocznik

2017

Tom

Vol. 24, nr 3

Strony

509--514

Opis fizyczny

Bibliogr. 12 poz., rys.

Twórcy

autor

Grodecki K.

kacper.grodecki@wat.edu.pl

Military University of Technology, Institute of Applied Physics, Gen. S. Kaliskiego 2, 00-908 Warsaw, Poland

autor

Martyniuk P.

piotr.martyniuk@wat.edu.pl

Military University of Technology, Institute of Applied Physics, Gen. S. Kaliskiego 2, 00-908 Warsaw, Poland

autor

Kopytko M.

malgorzata.kopytko@wat.edu.pl

Military University of Technology, Institute of Applied Physics, Gen. S. Kaliskiego 2, 00-908 Warsaw, Poland

autor

Kowalewski A.

andrzej.kowalewski@wat.edu.pl

Military University of Technology, Institute of Applied Physics, Gen. S. Kaliskiego 2, 00-908 Warsaw, Poland

autor

Stępień D.

dawid.stepien@wat.edu.pl

Military University of Technology, Institute of Applied P hysics, Gen. S. Kaliskiego 2, 00-908 Warsaw, Poland
Vigo System S.A., Poznańska 129/133, 05-850 Ożarow Mazowiecki, Poland

autor

Kębłowski A.

akeblowski@vigo.com.pl

Vigo System S.A., Poznańska 129/133, 05-850 Ożarow Mazowiecki, Poland

autor

Piotrowski A.

apiotrowski@vigo.com.pl

Vigo System S.A., Poznańska 129/133, 05-850 Ożarow Mazowiecki, Poland

autor

Piotrowski J.

jpiotrowski@vigo.com.pl

Vigo System S.A., Poznańska 129/133, 05-850 Ożarow Mazowiecki, Poland

autor

Gawron W.

wgawron@vigo.com.pl

Vigo System S.A., Poznańska 129/133, 05-850 Ożarow Mazowiecki, Poland

autor

Rogalski A.

antoni.rogalski@wat.edu.pl

Military University of Technology, Institute of Applied Physics, Gen. S. Kaliskiego 2, 00-908 Warsaw, Poland

Bibliografia

[1] Piotrowski, J., Rogalski, A. (2007). High-Operating-Temperature Infrared Photodetectors. SPIE, Bellingham.
[2] Piotrowski, J., Galus, M., Grudzien, M. (1991). Near room-temperature IR photo-detectors. Infrared Phys., 31(1), 1-48.
[3] Hunter, N., Mayorov, A.S., Wood, C.D., Russell, C., Li, L., Linfield, E.H., Davies, A.G., Cunningham, J.E. (2015). On-Chip Picosecond Pulse Detection and Generation Using Graphene Photoconductive Switches. Nano Lett., 15(3), 1591-1596.
[4] Newman, A.K., Liu, J.M. (1997). Physical characteristics of band-gap engineered, photovoltaic detectors. Journal of Applied Physics, 82(9), 4637-4646.
[5] Piotrowski, J., Gawron, W., Orman, Z., Pawluczyk, J., Kłos, K., Stępień, D., Piotrowski, A. (2010). Dark currents, responsivity, and response time in graded gap HgCdTe structures. Proc. SPIE, 7660, 766031.
[6] Spears, D.L. (1984). 10.6 micron photomixer arrays at 195. Proc. IRIS Active Systems, 331-349.
[7] Van Roosbroeck, W. (1950). Theory of the flow of electrons and holes in germanium and other semiconductors. Bell Syst. Tech. J., 29(4), 560-607.
[8] Kurata, M. (1982). Numerical Analysis for Semiconductor Devices. Lexington Books.
[9] Kopytko, M., Jóźwikowski, K., Jóźwikowska, A., Rogalski, A. (2010). High frequency response of near-room temperature LWIR HgCdTe heterostructure photodiodes. Opto-Electronics Rev., 18(3), 277-283.
[10] Jóźwikowski, K., Jóźwikowska, A., Kopytko, M., Rogalski, A., Jaroszewicz, L.R. (2012). Simplified model of dislocations as a SRH recombination channel in the HgCdTe heterostructures. Infrared Physics & Technology, 55(1), 98-107.
[11] Piotrowski, A., Madejczyk, P., Gawron, W., Kłos, K., Pawluczyk, J., Rutkowski, J., Piotrowski, J., Rogalski, A. (2007). Progress in MOCVD growth of HgCdTe heterostructures for uncooled infrared photodetectors. Infrared Phys. Technol., 49(3), 173-326.
[12] Stanaszek, D., Piotrowski, J., Piotrowski, A., Gawron, W., Orman, Z., Paliwoda, R., Brudnowski, M., Pawluczyk, J., Pedzinska, M. (2009). Mid and long infrared detection modules for picosecond range measurements. Proc. SPIE, 7482, 74820, M-74820, M-11.

Uwagi

This work was supported by Polish National Science Centre in the frame of the project NO. UMO-2013/08/A/ST5/00773

Opracowanie ze środków MNiSW w ramach umowy 812/P-DUN/2016 na działalność upowszechniającą naukę (zadania 2017).

Typ dokumentu

Bibliografia

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