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Atomically Thin Antimony-Doped Indium Oxide Nanosheets for Optoelectronics

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Nguyen, Chung Kim
Low, Mei Xiang
Zavabeti, Ali
Murdoch, Billy J.
Guo, Xiangyang
Aukarasereenont, Patjaree
Mazumder, Aishani
Dubey, Aditya
JANNAT, AZMIRA
Rahman, Md. Ataur

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Wiley-VCH Verlag GMBH

Abstract

Wide bandgap semiconducting oxides are emerging as potential 2D materials for transparent electronics and optoelectronics. This fuels the quest for discovering new 2D metal oxides with ultrahigh transparency and high mobility. While the former can be achieved by reducing the thickness of oxide films to only a few nanometers, the latter is more commonly realized by intentional doping. This article reports a one-step synthesis of few-unit-cell-thick and laterally large antimony-doped indium oxide (IAO). The doping process occurs spontaneously when the oxide is grown on the surface of a molten Sb–In alloy and 2D IAO nanosheets can be easily printed onto desired substrates. With thicknesses at the atomic scale, these materials exhibit excellent transparency exceeding 98% across the visible and near-infrared range. Field-effect transistors based on low-doped IAO nanosheets reveal a high electron mobility of ≈40 cm2 V−1 s−1. Additionally, a notable photoresponse is observed in 2D IAO-based photodetectors under ultraviolet (UV) radiation. Photoresponsivities of low-doped and highly doped IAO at a wavelength of 285 nm are found to be 1.2 × 103 and 0.7 × 103 A W−1, respectively, identifying these materials as promising candidates for the fabrication of high-performance optoelectronics in the UV region.

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Advanced Optical Materials

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Open Access

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Creative Commons Attribution licence

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