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Achieving Record-High Photoelectrochemical Photoresponse Characteristics by Employing Co 3 O 4 Nanoclusters as Hole Charging Layer for Underwater Optical Communication.

Yang KangDanhao WangYunzhi GaoSiqi GuoKejun HuBoyang LiuShi FangMuhammad Hunain MemonXin LiuYuanmin LuoXiyu SunDongyang LuoWei ChenLiuan LiHongfeng JiaWei HuZhenghui LiuBinghui GeHaiding Sun
Published in: ACS nano (2023)
The physicochemical properties of a semiconductor surface, especially in low-dimensional nanostructures, determine the electrical and optical behavior of the devices. Thereby, the precise control of surface properties is a prerequisite for not only preserving the intrinsic material quality but also manipulating carrier transport behavior for promoting device characteristics. Here, we report a facile approach to suppress the photocorrosion effect while boosting the photoresponse performance of n-GaN nanowires in a constructed photoelectrochemical-type photodetector by employing Co 3 O 4 nanoclusters as a hole charging layer. Essentially, the Co 3 O 4 nanoclusters not only alleviate nanowires from corrosion by optimizing the oxygen evolution reaction kinetics at the nanowire/electrolyte interface but also facilitate an efficient photogenerated carrier separation, migration, and collection process, leading to a significant ease of photocurrent attenuation (improved by nearly 867% after Co 3 O 4 decoration). Strikingly, a record-high responsivity of 217.2 mA W -1 with an ultrafast response/recovery time of 0.03/0.02 ms can also be achieved, demonstrating one of the best performances among the reported photoelectrochemical-type photodetectors, that ultimately allowed us to build an underwater optical communication system based on the proposed nanowire array for practical applications. This work provides a perspective for the rational design of stable nanostructures for various applications in photo- and biosensing or energy-harvesting nanosystems.
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