2010
DOI: 10.1117/12.852239
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Developing high-performance III-V superlattice IRFPAs for defense: challenges and solutions

Abstract: The antimonide superlattice infrared detector technology program was established to explore new infrared detector materials and technology. The ultimate goal is to enhance the infrared sensor system capability and meet challenging requirements for many applications. Certain applications require large-format focal plane arrays (FPAs) for a wide field of view. These FPAs must be able to detect infrared signatures at long wavelengths, at low infrared background radiation, and with minimal spatial cross talk. Othe… Show more

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Cited by 10 publications
(7 citation statements)
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“…94 Figure 37 shows tremendous progress made in past few years in the performance of type-II superlattice single element detectors or mini-arrays from USA major institutions: Northwestern University (NWU), Naval Research Laboratory (NRL), Jet Propulsion Laboratory (JPL), and Teledyne Imaging Scientific (TIS). 95 This figure shows superlattice detector performance through measurements of the dark current density as a multiple of Rule 07 versus time. The best SL device is within three times the value of HgCdTe Rule 07.…”
Section: Hgcdte Barrier Detectorsmentioning
confidence: 99%
“…94 Figure 37 shows tremendous progress made in past few years in the performance of type-II superlattice single element detectors or mini-arrays from USA major institutions: Northwestern University (NWU), Naval Research Laboratory (NRL), Jet Propulsion Laboratory (JPL), and Teledyne Imaging Scientific (TIS). 95 This figure shows superlattice detector performance through measurements of the dark current density as a multiple of Rule 07 versus time. The best SL device is within three times the value of HgCdTe Rule 07.…”
Section: Hgcdte Barrier Detectorsmentioning
confidence: 99%
“…Measured at 230 K spectral response curves show about 3.6 μm cut−off wave− length (at 50% of the initial rise in the response). Figure 20 shows tremendous progress made in the past few years in the performance of type−II superlattice single ele− ment detectors or mini−arrays from USA major institutions: Northwestern University (NWU), Naval Research Labora− tory (NRL), Jet Propulsion Laboratory (JPL), and Teledyne Imaging Scientific (TIS) [56]. This figure shows super− lattice detector performance measured by dark current den− sity as a multiple of "Rule 07" vs. time in years.…”
Section: Hgcdte Barrier Detectorsmentioning
confidence: 99%
“…Figure 5(a) and (b) compare the dark current performance of type II SLS detectors from various groups with a "Rule 07" model providing a theoretical prediction of MCT detector performance as a function of wavelength and over time, respectively [7,110,[40][41][42]. Likewise, Figure 6(a) and (b) chart the carrier lifetimes at 77 K for HgCdTe and type II SLS detectors operating at MWIR and LWIR wavelengths, respectively, as a function of doping concentration [11].…”
Section: Development Of Type II Sls Detectorsmentioning
confidence: 99%
“…(a) Dark current densities plotted against cutoff wavelength for type II SLS non-barrier and barrier detectors at 78 K [7,11]. The solid line indicates the dark current density calculated using the empirical "rule 07" model, and the circle indicates results from DeCuir et al [39] (b) Detector dark current density as multiple of rule 07 [40][41][42]. The black line represents the trend line of dark current reduction over time for single element detectors, while the red line shows this trend for FPAs.…”
Section: Development Of Type II Sls Fpasmentioning
confidence: 99%