Analysis, Optimization, and Design of 2-2.8 \mu \hbox Stacked Multiple-Junction PIN GaInAsSb/GaSb Photodetectors for Future O/E Interconnections

Analysis, Optimization, and Design of 2-2.8 \mu \hbox Stacked Multiple-Junction PIN GaInAsSb/GaSb Photodetectors for Future O/E Interconnections

The 2-2.8 μm vertically stacked multiple-junction PIN GalnAsSb/GaSb photodetectors are analyzed, optimized, and designed based on an improved general mode to predict the optimal performance of PIN infrared photodetectors arising from nonequilibrium carrier generation, diffusion, and recombination th...

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Bibliographic Details
Published in:IEEE transactions on electron devices Vol. 57; no. 2; pp. 361 - 367
Main Authors: Bangli Liang, Dianyong Chen, Bo Wang, Kwasniewski, T.A., Zhigong Wang
Format: Journal Article
Language:English
Published: IEEE 01-02-2010
Subjects:
Absorption
Data models
Detectors
GaInAsSb/GaSb
Junctions
multiple junction
optical-electrical (O/E) interconnections
photodetectors
PIN
PIN photodiodes
Surface treatment
vertically stacked
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Summary:The 2-2.8 μm vertically stacked multiple-junction PIN GalnAsSb/GaSb photodetectors are analyzed, optimized, and designed based on an improved general mode to predict the optimal performance of PIN infrared photodetectors arising from nonequilibrium carrier generation, diffusion, and recombination theory. Optimal thickness of intrinsic absorption region (Wopt), response quantum efficiency (RQE), detectivity (D*), and -3-dB cutoff frequency (f _3dB ) are calculated and optimized for a 2-2.8 μm room-temperature high-frequency operation. Ways to achieve optimal performance in practice, material, and device structures are proposed. The optimized vertically stacked multiple-junction PIN GalnAsSb/GaSb photodetector structure shows a D* of (1.6-1.9) × 10 12 cm· Hz 1/2 /W,an RQE of 52%-69%, and a f - 3 dB ≫ 20 GHz with W opt = 3 μm and junction number K = 5, effective illumination area A d = 1000 μm 2 , and reverse bias voltage V RB = 0.5 V. The proposed general model is validated by simulation and measurement data of fabricated single-junction detectors.
ISSN:0018-9383
1557-9646
DOI:10.1109/TED.2009.2036303