Tunable thermo-phototronic effect in unintentionally doped n-3C-SiC/p-Si heterostructure
Article
Nguyen, Hung, Nguyen, Duy Van, Tran, Thi Lap, Song, Pingan, Hong, Min, Dao, Dzung Viet, Nguyen, Nam-Trung, Bell, John and Dinh, Toan. 2024. "Tunable thermo-phototronic effect in unintentionally doped n-3C-SiC/p-Si heterostructure." Applied Physics Letters. 124 (15). https://doi.org/10.1063/5.0187276
Article Title | Tunable thermo-phototronic effect in unintentionally doped n-3C-SiC/p-Si heterostructure |
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ERA Journal ID | 949 |
Article Category | Article |
Authors | Nguyen, Hung, Nguyen, Duy Van, Tran, Thi Lap, Song, Pingan, Hong, Min, Dao, Dzung Viet, Nguyen, Nam-Trung, Bell, John and Dinh, Toan |
Journal Title | Applied Physics Letters |
Journal Citation | 124 (15) |
Article Number | 152104 |
Number of Pages | 7 |
Year | 2024 |
Publisher | AIP Publishing |
Place of Publication | United States |
ISSN | 0003-6951 |
1077-3118 | |
Digital Object Identifier (DOI) | https://doi.org/10.1063/5.0187276 |
Web Address (URL) | https://pubs.aip.org/aip/apl/article-abstract/124/15/152104/3282231/Tunable-thermo-phototronic-effect-in |
Abstract | The convergence of the Internet of Things (IoT) and 5G technology is creating a high demand in sensor signals, prompting a shift toward self-powered sensors as eco-friendly alternatives to the conventional battery-powered ones. The 3C–SiC/Si heterostructure recently has gained significant attention for sensing applications, including self-powered sensors. However, it has remained unclear about the sensing properties and the underlying physics of the sensing mechanism of the unintentionally doped n-SiC/p-Si heterostructure, hindering the design optimization of SiC/Si heterojunction self-powered devices for diverse applications. This study investigates the thermo-phototronic effect and its underlying mechanism in an unintentionally doped n-3C–SiC/p-Si heterostructure for self-powered sensors. The sensors can be self-powered by absorbing energy from photons to generate photovoltage and photocurrent as high as 110 mV and 0.8 μA. In addition, widening the electrode spacing increased the photovoltage of the device by as much as 122% and the photocurrent by as much as 65%. When the temperature gradient is progressively increased by heating one electrode, the photovoltage decreases gradually, while the current exhibits an initial increase of up to 10%, followed by a decline. These tunable characteristics are attributed to the capability of the heterostructure to control the transport of charge carriers and the impact of unintentionally doped n-SiC on the diffusion of charge carriers. The results of this study can be applied in the development of photodetectors, thermal sensors, and position detectors with tunable sensing performance. |
Keywords | Photovoltaic effects; Optoelectronics; Thermoelectric effects; Semiconductor temperature sensors; Photodetectors; Heterostructures |
Contains Sensitive Content | Does not contain sensitive content |
ANZSRC Field of Research 2020 | 401605. Functional materials |
Public Notes | This article may be downloaded for personal use only. Any other use requires prior permission of the author and AIP Publishing. This article appeared in Appl. Phys. Lett. 124, 152104 (2024) and may be found at https://doi.org/10.1063/5.0187276. |
Byline Affiliations | Centre for Future Materials |
School of Engineering | |
Griffith University |
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