Low-voltage-operation avalanche photodiode based on n-gallium oxide/p-crystalline selenium heterojunction

Imura, Shigeyuki; Kikuchi, Kenji; Miyakawa, Kazunori; Ohtake, Hiroshi; Kubota, Minoru

doi:10.1063/1.4883649

Cited by 33 publications

(7 citation statements)

References 20 publications

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“…For gallium oxide, avalanche photodiodes have been fabricated with the use of heterostructures. [ 128 ] Mahmoud [ 69 ] has fabricated avalanche photodetector based on β‐Ga 2 O 3 /SnO 2 bilayer heterostructure with an avalanche gain of 1.7 × 10 5 at reverse bias of −5.5 V. The SnO 2 layer was deposited by RF Sputtering while the β‐Ga 2 O 3 layer was performed by a cation exchange mechanism to reduce the lattice mismatch between the two layers at the interface between them. Figure a shows the energy band diagram elucidating the mechanism of APD at a forward and reverse bias.…”

Section: Varied Device Geometries—working Principle With Examplesmentioning

confidence: 99%

“…After a certain applied bias, the photogenerated carriers acquire high enough velocity under the action of the high electric field to cause impact ionization and hence cause a rapid increase in the photocurrent. [127][128] The other mechanism that is ascribed for the high photoconductive gain is the formation of STHs and their subsequent lowering of effective Schottky barrier height. These STHs are thought to occur in the gallium oxide material itself as opposed to the hole trapping by the defect states at the Schottky metal contact.…”

Section: The Functional Material-gallium Oxide: Properties For Photodetection Applicationsmentioning

confidence: 99%

See 1 more Smart Citation

A Strategic Review on Gallium Oxide Based Deep‐Ultraviolet Photodetectors: Recent Progress and Future Prospects

Kaur

Kumar

2021

Advanced Optical Materials

245

153

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With the use of UV‐C radiation sterilizers on the rise in the wake of the recent pandemic, it has become imperative to have health safety systems in place to curb the ill‐effects on humans. This requires detection systems with suitable spectral response to the “invisible to the naked eye” radiation leaks with utmost sensitivity and swiftness. State of the art deep‐UV photodetectors based on the wide bandgap material gallium oxide have achieved responsivities up to few hundred A W−1 while the minimum response time achieved is few hundred nanoseconds. However, due to the trade‐off between these two key parameters, the ultimate performance of the photodetectors remains inadequate. The focus here is to give a thorough review of the gallium oxide based photodetectors, their recent progress and future prospects. This review highlights the fundamental physics and the key parameters such as dark current, responsivity, and response time with their dependence on the material properties. Exploration of the reasons behind current scenario in the field of gallium oxide is comprehensively and critically analyzed. The key challenges which limit device performance and inhibit the realization of real‐world practical detectors are also described. The lacunae currently plaguing the field is also discussed with possible remedial solutions.

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Section: Varied Device Geometries—working Principle With Examplesmentioning

confidence: 99%

Section: The Functional Material-gallium Oxide: Properties For Photodetection Applicationsmentioning

confidence: 99%

A Strategic Review on Gallium Oxide Based Deep‐Ultraviolet Photodetectors: Recent Progress and Future Prospects

Kaur

Kumar

2021

Advanced Optical Materials

245

153

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“…The solaristor (a portmanteau of SOLAR cell transISTOR) is the compact two terminal self-powered phototransistor (with a normallyoff state), or in other words, a solar cell and a memristor in series (Fig. 8 (a) Conventional phototransistors exhibit photoconductive gain, which is not seen in photodiodes (except avalanche photodiodes [569] , [570] ), and results in external quantum efficiencies (EQEs) well over 100%. For example, for an image sensor pixel in low lighting, photoconductive gain in the phototransistor enables higher EQEs than the photodiode-based pixel [571] .…”

Section: Switchable Buffers: Solaristor -A Neuromorphic Phototransistormentioning

confidence: 99%

Functional Oxides for Photoneuromorphic Engineering: Toward a Solar Brain

Pérez‐Tomás

2019

Adv Materials Inter

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New device concepts and new computing principles are needed to balance our ever-growing appetite for data and information with the realization of the goals of increased energy efficiency, reduction in CO 2 emissions and the circular economy. Neuromorphic or synaptic electronics is an emerging field of research aiming to overcome the current computer's Von-Neumann bottleneck by building artificial neuronal systems to mimic the extremely energy efficient biological synapses. The introduction of photovoltaic and/or photonic aspects into these neuromorphic architectures will produce self-powered adaptive electronics but may also open up new possibilities in artificial neuroscience, artificial neural communications, sensing and machine learning which would enable, in turn, a new era for computational systems owing to the possibility of attaining high bandwidths with much reduced power consumption. This perspective is focused on recent progress in the implementation of functional oxide thinfilms into photovoltaic and neuromorphic applications towards the envisioned goal of selfpowered photovoltaic neuromorphic systems or a solar brain.

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“…The advantage is that polycrystalline Se can be fabricated on almost all types of substrates and the disadvantage is that crystal grains must be controlled to flatten the surface of the c-Se layer to obtain high-quality images. Previously, employing a wide-bandgap n-type semiconducting gallium oxide (Ga 2 O 3 ) as a hole blocking layer, we reported avalanche multiplication at a low reverse bias voltage in a c-Se-based photodiode fabricated on a glass substrate, which exhibited extremely high external quantum efficiency (EQE) of more than 100% 22 .…”

Section: Introductionmentioning

confidence: 99%

Enhanced image sensing with avalanche multiplication in hybrid structure of crystalline selenium photoconversion layer and CMOSFETs

Imura

Mineo

Honda

et al. 2020

Sci Rep

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The recent improvements of complementary metal–oxide–semiconductor (CMOS) image sensors are playing an essential role in emerging high-definition video cameras, which provide viewers with a stronger sensation of reality. However, the devices suffer from decreasing sensitivity due to the shrinkage of pixels. We herein address this problem by introducing a hybrid structure comprising crystalline-selenium (c-Se)-based photoconversion layers and 8 K resolution (7472 × 4320 pixels) CMOS field-effect transistors (FETs) to amplify signals using the avalanche multiplication of photogenerated carriers. Using low-defect-level NiO as an electric field buffer and an electron blocking layer, we confirmed signal amplification by a factor of approximately 1.4 while the dark current remained low at 2.6 nA/cm2 at a reverse bias voltage of 22.6 V. Furthermore, we successfully obtained a brighter image based on the amplified signals without any notable noise degradation.

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Low-voltage-operation avalanche photodiode based on n-gallium oxide/p-crystalline selenium heterojunction

Cited by 33 publications

References 20 publications

A Strategic Review on Gallium Oxide Based Deep‐Ultraviolet Photodetectors: Recent Progress and Future Prospects

A Strategic Review on Gallium Oxide Based Deep‐Ultraviolet Photodetectors: Recent Progress and Future Prospects

Functional Oxides for Photoneuromorphic Engineering: Toward a Solar Brain

Enhanced image sensing with avalanche multiplication in hybrid structure of crystalline selenium photoconversion layer and CMOSFETs

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