Resonator-QWIP FPA development

Choi, K. K.; Sun, Jason; Olver, K.

doi:10.1117/12.2176446

Cited by 3 publications

(2 citation statements)

References 4 publications

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“…Furthermore, a wide range of doping concentrations (0.6-4 × 10 17 cm -3 ) could maintain the QE beyond 60% giving rise to a robustness for varying doping concentration. The regularities of the R-QWIP (Sun et al 2017;Choi et al 2015) are much different from the results of the MC-QWIP. The simulated QE of the R-QWIP (Sun et al 2017) is proportional to the doping concentration and ranges from 30% to 70% when the doping concentration increases from 0.2 × 10 18 cm -3 to 1.0 × 10 18 cm -3 .…”

Section: Simulation and Analysismentioning

confidence: 63%

“…Thus, the resonance effect is weak and the QW absorption decreases with the decreasing doping concentration while the bandwidth basically remains unchanged. This is the case of the R-QWIP (Sun et al 2017;Choi et al 2015). As to the MC-QWIP, due to the reflection on the Ti/Au side wall, the number of the light passes through the QW active layer is more than that in the R-QWIP.…”

Section: Analysis With Waveguide Modelmentioning

confidence: 99%

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Metallic cavity quantum well infrared photodetector for filter-free SF6 gas imaging

et al. 2021

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Generally, for gas imaging, narrowing the response of the camera sensor around the target gas's absorption band would increase the imaging contrast. In this paper, A filter-free narrowband metallic cavity quantum well infrared photodetector is proposed. The metallic cavity is formed by Ti/Au film coating on the detector's mesa. The geometry of the cavity is properly designed to sustain cavity mode resonating at 10.6 μm. With strong resonance, the absorption efficiency of the embedded quantum well active layer maintains high level (~74%) even with a fairly low doping concentration (~1×10 17 cm -3 ). And the bandwidth is as narrow as 0.22 μm. A waveguide model is presented and used to analyze the metal cavity quantum well infrared photodetector, and it is found that the metal film coating on the side wall played an important role in enhancing the resonance and narrowing the spectral line width.

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Section: Simulation and Analysismentioning

confidence: 63%

Section: Analysis With Waveguide Modelmentioning

confidence: 99%

Metallic cavity quantum well infrared photodetector for filter-free SF6 gas imaging

et al. 2021

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High-x InP/InxGa1−xAs quantum well infrared photodetector

Besikci

2018

Infrared Physics & Technology

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Materials design parameters for infrared device applications based on III-V semiconductors

et al. 2016

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The collaborative development of infrared detector materials by the Army Research Laboratory and Stony Brook University has led to new fundamental understandings of materials, as well as new levels of control and flexibility in III-V semiconductor crystal growth by molecular beam epitaxy. Early work on mid-wave strained layer superlattice (SLS) cameras led to a subsequent focus on minority carrier lifetime studies, which resulted in the proposal of the Ga-free SLS on GaSb substrates. The later demonstration of virtual substrate technology allowed the lattice constant to become a design parameter and enabled growth of undistorted bulk InAsSb. When grown in that manner, InAsSb has a bandgap bowing parameter large enough to cover absorption wavelengths across the entire long-wavelength band (8-12 μm). Even longer wavelengths are achieved with a general Ga-free SLS approach, with a virtual substrate having a lattice constant significantly larger than that of GaSb and with InAsSb in both bi-layers in the period. Since these layers can also be made very thin, the general Ga-free SLS does not suffer from the relatively low optical absorption and poor hole transport, which is characteristic of the special Ga-free SLS on GaSb for long-wavelength designs. Finally, the general Ga-free InAsSb SLS provides a method to induce and control sustained atomic ordering, which is yet another new design parameter.

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Resonator-QWIP FPA development

Cited by 3 publications

References 4 publications

Metallic cavity quantum well infrared photodetector for filter-free SF6 gas imaging

Metallic cavity quantum well infrared photodetector for filter-free SF6 gas imaging

High-x InP/InxGa1−xAs quantum well infrared photodetector

Materials design parameters for infrared device applications based on III-V semiconductors

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