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Paper detail

Visualizing an adjustable WO3/p-GaN heterojunction

The p-n junctions based on typical semiconductors are the elementary units for the modern electronic devices and chip industry. While the rectification property of those p-n junction is usually fixed once the unit is fabricated. Here, we proposed an adjustable n-WO3/p-GaN heterojunction with controllable electronic properties. For the prepared n-WO3/p-GaN heterojunction, it is almost transparent and shows typical p-n junction rectification. While if gradually doping some hydrogen atoms into WO3 layer by a facile electron-proton synergistic route, the heterojunction can be turned dynamically from the typical p-n junction (n-WO3/p-GaN) to standard Schottky contact (HxWO3/p-GaN) step by step. More importantly, this evolution can be directly visualized by eyesight due to the pronounced electrochromic characteristic of WO3 layer. By connecting two HxWO3/p-GaN heterojunctions, the controllable bi-functional rectification can be achieved. In addition, the HxWO3/p-GaN heterojunction can recovered to the original p-n jucntion just by annealing at ambient, demonstrating the heterojunction is controllable and reusable. The current study will open up tremendous opportunities for dynamic electronic devices in the future.

preprint2020arXivOpen access
Yuliang ChenChanglong HuGuobin ZhangChongwen Zou
physics.app-phcond-mat.mtrl-sci
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Yuliang ChenChanglong HuGuobin ZhangChongwen Zou

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