Journal
QUANTUM SENSING AND NANO ELECTRONICS AND PHOTONICS XVII
Volume 11288, Issue -, Pages -Publisher
SPIE-INT SOC OPTICAL ENGINEERING
DOI: 10.1117/12.2543896
Keywords
type-II superlattice; infrared detector; quantum efficiency; digital; focal plane array
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Funding
- NASA Earth Science Technology Office
- National Aeronautics and Space Administration [80NM0018D004]
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In this invited paper, we will report our recent efforts in achieving high performance in Antimonides type-II superlattice (T2SL) based infrared photodetectors using the barrier infrared detector (BIRD) architecture. The initial BIRD devices (such as the nBn and the XBn) used either InAs absorber grown on InAs substrate, or lattice-matched InAsSb alloy grown on GaSb substrate, with cutoff wavelengths of similar to 3.2 mu m and similar to 4 mu m, respectively. While these detectors could operate at much higher temperatures than existing MWIR detectors based on InSb, their spectral responses do not cover the full (3 - 5.5 mu m) MWIR atmospheric transmission window. The T2SL BIRD devices not only covers the full MWIR atmospheric transmission window, but the full LWIR atmospheric transmission window and beyond. The LWIR detectors based on the BIRD architecture has also demonstrated significant operating temperature advantages over those based on traditional p-n junction designs. Two 6U SmalSat missions CIRAS (Cubesat Infrared Atmospheric Sounder) and HyTI ( Hyperspectral Thermal Imager) are based on JPL's T2SL BIRD focal plane arrays (FPAs). Based on III-V compound semiconductors, the BIRD FPAs offer a breakthrough solution for the realization of low cost (high yield), high- performance FPAs with excellent uniformity and pixel-to-pixel operability.
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