Reprogrammable Binary and Ternary Optoelectronic Logic Gates Composed of Nanostructured GaN Photoelectrodes with Bipolar Photoresponse Characteristics

Luo, Yuanmin; Wang, Danhao; Kang, Yang; Fang, Shi; Liu, Xin; Chen, Wei; Yu, Huabin; Jia, Hongfeng; Memon, Muhammad Hunain; Zhang, Haochen; Luo, Dongyang; Xiao, Sun; Li, Liuan; He, Jr‐Hau; Sun, Haiding

doi:10.1002/adom.202300129

Cited by 16 publications

(7 citation statements)

References 65 publications

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“…The input is designated as “1” if the corresponding light source is activated and illuminates the photoelectrode TiO 2 , and “0” if not. The photocurrent is recognized as the output and is labeled “1” if it exceeds −7.4 μA or falls below −9.1 μA, and designated “0” otherwise. ,, At −0.7 V vs SCE, light irradiation (254 nm, 1800 μW·cm –2 ) leads to negative photocurrent, resulting from electron transfer to the solution followed by its reduction with electron acceptors in NaOH solution. Inversely, illumination with light (365 nm, 1800 μW·cm –2 ) generates a positive photocurrent, which can be attributed to the transfer of electrons to the external circuit structure.…”

Section: Results and Discussionmentioning

confidence: 99%

Modulation of Bipolar Ultraviolet Current in TiO₂ Nanofilms for Switching Logic Devices via Ti Valence State Control

Lai,

Jin,

et al. 2023

ACS Appl. Nano Mater.

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Section: Results and Discussionmentioning

confidence: 99%

Modulation of Bipolar Ultraviolet Current in TiO₂ Nanofilms for Switching Logic Devices via Ti Valence State Control

Lai,

Jin,

et al. 2023

ACS Appl. Nano Mater.

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“…Essentially, due to their electrolyte-assisted operating characteristics, the operation principle of PEC-type devices not only follows the conventional carrier generation, separation, and migration processes in semiconductors but also encompasses a unique electrochemical procedure that involves the redox reaction at the semiconductor/electrolyte interface, providing us more freedom to regulate their photoresponse behavior [ 6 , 7 ]. Thus far, the PEC-type devices have unleashed their potential in the fields of underwater optical communication [ 8 ], optoelectronic logic [ 9 ], artificial vision [ 2 ], automatic imaging [ 10 ], energy conversion catalysis [ 11 ], etc. Additionally, the unique electrolyte-assisted operation might also enable PEC-type devices for possible liquid-based biosensing, including glucose detection, DNA detection, and cell detection [ 12 – 14 ].…”

Section: Introductionmentioning

confidence: 99%

Facile Semiconductor p–n Homojunction Nanowires with Strategic p-Type Doping Engineering Combined with Surface Reconstruction for Biosensing Applications

Li,

Fang,

Chen

et al. 2024

Nano-Micro Lett.

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Photosensors with versatile functionalities have emerged as a cornerstone for breakthroughs in the future optoelectronic systems across a wide range of applications. In particular, emerging photoelectrochemical (PEC)-type devices have recently attracted extensive interest in liquid-based biosensing applications due to their natural electrolyte-assisted operating characteristics. Herein, a PEC-type photosensor was carefully designed and constructed by employing gallium nitride (GaN) p–n homojunction semiconductor nanowires on silicon, with the p-GaN segment strategically doped and then decorated with cobalt–nickel oxide (CoNiOx). Essentially, the p–n homojunction configuration with facile p-doping engineering improves carrier separation efficiency and facilitates carrier transfer to the nanowire surface, while CoNiOx decoration further boosts PEC reaction activity and carrier dynamics at the nanowire/electrolyte interface. Consequently, the constructed photosensor achieves a high responsivity of 247.8 mA W−1 while simultaneously exhibiting excellent operating stability. Strikingly, based on the remarkable stability and high responsivity of the device, a glucose sensing system was established with a demonstration of glucose level determination in real human serum. This work offers a feasible and universal approach in the pursuit of high-performance bio-related sensing applications via a rational design of PEC devices in the form of nanostructured architecture with strategic doping engineering.

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“…However, most of these traditional transistors were silicon-based ones, making further miniaturization and integration challenging, which is a significant drawback in the post-Moore era. Fortunately, recent research indicates that optoelectronic logic devices based on two-dimensional materials , and photoelectrochemical (PEC) devices operating in an electrolyte solution environment can effectively overcome this limitation. The most feasible method to obtain homojunction devices is through local electrostatic doping using a semifloating gate , or split gate. , However, operating homojunction-based logic devices is not straightforward; they require simultaneous optical and electrical signals for proper functioning.…”

Section: Introductionmentioning

confidence: 99%

Photocurrent Ambipolar Behavior in Phase Junction of a Ga₂O₃ Porous Nanostructure for Solar-Blind Light Control Logic Devices

Ye,

Jin,

Cheng

et al. 2024

ACS Appl. Mater. Interfaces

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Photoelectrochemical (PEC) devices are the most similar artificial devices to the nervous system, which is expected to solve the problem of complex computer/nervous system interface (solid–liquid interface) and multifunctional integration (photoelectric fusion) required in the post-Moore era. Based on the different photocurrent ambipolar behavior and different deep ultraviolet solar-blind spectral photoresponse characteristics of α-Ga2O3 and β-Ga2O3, we designed and constructed the Ga2O3 porous nanostructure PEC device with an adjustable photocurrent bipolar behavior through constructing an α/β phase junction core–shell structure by adjusting the thickness and the surface state of the shell layer. The switching point of the α/β-Ga2O3 ambipolar photocurrent shifts toward negative values with the increase of β-Ga2O3 shell layer thicknesses, and adjustable Boolean logic gates are prepared using the voltage as the input source with a high accuracy manipulated by solar-blind deep ultraviolet light. The controllable solar-blind logic gates based on the ambipolar photocurrent behavior of α/β-Ga2O3 presented in this study offer a new path for the photoelectric device multifunctional integration needed in the post-Moore era, which can be used in the creation of Ga2O3 half adders and full adders, as well as in the construction of four-input OR gates.

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Reprogrammable Binary and Ternary Optoelectronic Logic Gates Composed of Nanostructured GaN Photoelectrodes with Bipolar Photoresponse Characteristics

Cited by 16 publications

References 65 publications

Modulation of Bipolar Ultraviolet Current in TiO₂ Nanofilms for Switching Logic Devices via Ti Valence State Control

Modulation of Bipolar Ultraviolet Current in TiO₂ Nanofilms for Switching Logic Devices via Ti Valence State Control

Facile Semiconductor p–n Homojunction Nanowires with Strategic p-Type Doping Engineering Combined with Surface Reconstruction for Biosensing Applications

Photocurrent Ambipolar Behavior in Phase Junction of a Ga₂O₃ Porous Nanostructure for Solar-Blind Light Control Logic Devices

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Reprogrammable Binary and Ternary Optoelectronic Logic Gates Composed of Nanostructured GaN Photoelectrodes with Bipolar Photoresponse Characteristics

Cited by 16 publications

References 65 publications

Modulation of Bipolar Ultraviolet Current in TiO2 Nanofilms for Switching Logic Devices via Ti Valence State Control

Modulation of Bipolar Ultraviolet Current in TiO2 Nanofilms for Switching Logic Devices via Ti Valence State Control

Facile Semiconductor p–n Homojunction Nanowires with Strategic p-Type Doping Engineering Combined with Surface Reconstruction for Biosensing Applications

Photocurrent Ambipolar Behavior in Phase Junction of a Ga2O3 Porous Nanostructure for Solar-Blind Light Control Logic Devices

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Modulation of Bipolar Ultraviolet Current in TiO₂ Nanofilms for Switching Logic Devices via Ti Valence State Control

Modulation of Bipolar Ultraviolet Current in TiO₂ Nanofilms for Switching Logic Devices via Ti Valence State Control

Photocurrent Ambipolar Behavior in Phase Junction of a Ga₂O₃ Porous Nanostructure for Solar-Blind Light Control Logic Devices