Litcius/Paper detail

High-gain low-excess-noise MWIR detection with a 3.5-<i>µ</i>m cutoff AlInAsSb-based separate absorption, charge, and multiplication avalanche photodiode

Adam A. Dadey, J. Andrew McArthur, Abhilasha Kamboj, Seth R. Bank, Daniel Wasserman, Joe C. Campbell

2023APL Photonics20 citationsDOIOpen Access PDF

Abstract

Mid-wavelength infrared (MWIR) detection is useful in a variety of scientific and military applications. Avalanche photodiodes can provide an advantage for detection as their internal gain mechanism can increase the system signal-to-noise ratio of a receiver. We demonstrate a separate absorption, charge, and multiplication avalanche photodiode using a digitally grown narrow-bandgap Al0.05InAsSb absorber for MWIR detection and a wide bandgap Al0.7InAsSb multiplier for low-excess-noise amplification. Under 2-µm illumination at 100 K, the device can reach gains over 850. The excess noise factor of the device scales with a low k-factor of ∼0.04. The unity-gain external quantum efficiency of the device attains a peak of 54% (1.02 A/W) at 2.35 µm and maintains an efficiency of 24% (0.58 A/W) at 3 µm before cutting off at ∼3.5 µm. At a gain of 850, the device has a gain-normalized dark current density of 0.05 mA/cm2. This device achieves gains more than double that of the state-of-the-art InAs detectors and achieves gain-normalized dark current densities over two orders of magnitude lower than that of a previously reported MWIR Al0.15InAsSb-based detector.

Topics & Concepts

Avalanche photodiodeDark currentPhotodiodeOptoelectronicsQuantum efficiencyNoise (video)PhysicsDetectorCutoff frequencyNoise figureOpticsMaterials scienceCMOSImage (mathematics)Computer scienceArtificial intelligenceAmplifierAdvanced Semiconductor Detectors and MaterialsSemiconductor Quantum Structures and DevicesSpectroscopy and Laser Applications