Three-dimensional metal–semiconductor–metal bipolar ultraviolet phototransistor based on GaN p-i-n epilayer

Three-dimensional metal–semiconductor–metal bipolar ultraviolet phototransistor based on GaN p-i-n epilayer

GaN-based ultraviolet (UV) detectors have a considerable application potential in many fields. In this Letter, we report an alternative strategy to realize a high-optical-gain bipolar UV phototransistor based solely on a GaN p-i-n epilayer. The device consists of two tightly adjacent vertical p-i-n...

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Bibliographic Details
Published in:Applied physics letters Vol. 119; no. 16
Main Authors: Jiang, Ke, Sun, Xiaojuan, Chen, Yuxuan, Zhang, Shanli, Ben, Jianwei, Chen, Yang, Zhang, Zi-Hui, Jia, Yuping, Shi, Zhiming, Li, Dabing
Format: Journal Article
Language:English
Published: Melville American Institute of Physics 18-10-2021
Subjects:
Applied physics
Emission
Emitters
Gallium nitrides
Mesas
Photometers
Phototransistors
Quantum efficiency
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Summary:GaN-based ultraviolet (UV) detectors have a considerable application potential in many fields. In this Letter, we report an alternative strategy to realize a high-optical-gain bipolar UV phototransistor based solely on a GaN p-i-n epilayer. The device consists of two tightly adjacent vertical p-i-n structures with a common n-type layer as a floating base. The collector and emitter electrodes are deposited on the two p-type mesas, forming a three-dimensional metal–semiconductor–metal (MSM) like photodetector. As a result, a peak responsivity of 11.7 A/W at a wavelength of 358 nm at 5 V is realized, corresponding to an optical gain of 40 with the assumption of 100% internal quantum efficiency. Different from traditional GaN-based n-p-i-n phototransistors, the optical gain of this detector originates from the accumulated electrons in the n-type floating base upon illumination, which can lower the barrier height between the base and emitter, leading to hole emission from the emitter. Although the structure of this phototransistor is similar to a planar back-to-back Schottky-type MSM photodetector, the response speed is much faster because the gain mainly results from carrier emission rather than MS interface defects.
ISSN:0003-6951
1077-3118
DOI:10.1063/5.0064779