Effect of Multiplication and Charge Layers on the Gain in InGaAsSb/AlGaAs Avalanche Photodiodes at Room Temperature

Effect of Multiplication and Charge Layers on the Gain in InGaAsSb/AlGaAs Avalanche Photodiodes at Room Temperature

This paper presents a theoretical analysis of npBp infrared (IR) barrier avalanche photodiode (APD) performance operating at 300 K based on a quaternary compound made of A<sup>III</sup>B<sup>V</sup>—InGaAsSb, lattice-matched to the GaSb substrate with a <i>p</i>-t...

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Bibliographic Details
Main Authors: Tetiana Manyk, Jarosław Rutkowski, Krzysztof Kłos, Nathan Gajowski, Sanjay Krishna, Piotr Martyniuk
Format: Article
Language:English
Published: MDPI AG 2025-04-01
Series:Sensors
Subjects:
SWIR
IR detectors
avalanche detectors
APDs
impact multiplication gain
InGaAsSb
Online Access:https://www.mdpi.com/1424-8220/25/7/2255
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Summary:This paper presents a theoretical analysis of npBp infrared (IR) barrier avalanche photodiode (APD) performance operating at 300 K based on a quaternary compound made of A<sup>III</sup>B<sup>V</sup>—InGaAsSb, lattice-matched to the GaSb substrate with a <i>p</i>-type barrier made of a ternary compound AlGaSb. Impact ionization in the multiplication layer of InGaAsSb separate absorption, grading, charge, and multiplication avalanche photodiodes (SAGCM APDs) was studied using the Crosslight Software simulation package APSYS. The band structure of the avalanche detector and the electric field distribution for the multiplication and absorption layers were determined. The influence of the multiplication and charge layer parameters on the impact multiplication gain and the excess noise factor was analyzed. It has been shown that with the decrease in the charge layer doping level, the gain and the breakdown voltage increase, but the punch-through voltage decreases, and the linear range of the APD operating voltages widens. The multiplication layer doping level slightly affects the detector parameters, while increasing its width, the photocurrent and the breakdown voltage also increase. The detector structure proposed in this work allows us to obtain a comparable gain and lower dark currents to the APD detectors made of InGaAsSb previously presented in the literature. The performed simulations confirmed the possibility of obtaining APDs with high performance at room temperatures made of InGaAsSb for the SWIR range.
ISSN:1424-8220

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