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Abstract

Bi ₂O ₂Se is a new type of semiconductor material, which has the advantages of high carrier mobility, air stability, strong spin-orbit coupling, etc. It has a variety of synthesis methods and a wide range of applications. In the past few years, many explorations have been made in the synthesis, large-size growth, and applications of Bi ₂O ₂Se. It has been applied to field effect transistors, infrared photodetectors, semiconductor devices, heterojunctions, spin electronics, etc. Since nanowire has a larger surface area-to-volume ratio than nano-film, nanowire may have greater advantages in gate regulation and strong spin-orbit coupling, and these properties can play a crucial role in certain fields. However, most of the studies focused on its two-dimensional films, and there are less researches of its one-dimensional counterpart. In this work, a method of growing Bi ₂O ₂Se one-dimensional nanowires by chemical vapor deposition in a three-temperature-zone tubular furnace is introduced. High-quality suspended Bi ₂O ₂Se nanowires are obtained. In addition, the effects on the Bi ₂O ₂Se nanowire growth of the position of the mica substrates, i.e, different horizontal positions and vertical heights in the quartz boat, are studied, and the optimal conditions for the growth are summarized. The nanowires are characterized by atomic force microscope and energy dispersive spectrometer to show the information about the size and component. Then, superconducting quantum interference device based on the Bi ₂O ₂Se nanowires is constructed, and the superconducting quantum interference in a magnetic field is observed, which provides a way to broaden the application of Bi ₂O ₂Se nanowires.

Keywords:

Bi₂O₂Se nanowires/
chemical vapor deposition/
superconducting quantum interference devices

Authors and contacts

Corresponding author:Lü Li,lilu@iphy.ac.cn; Qu Fan-Ming,fanmingqu@iphy.ac.cn

Funds:Project supported by the National Key Research and Development Program of China (Grant No. 2022YFA1403400), the National Natural Science Foundation of China (Grant Nos. 12074417, 92065203), the Strategic Priority Research Program of the Chinese Academy of Sciences, China (Grant Nos. XDB28000000, XDB33000000), the Synergetic Extreme Condition User Facility sponsored by the National Development and Reform Commission, and the Innovation Program for Quantum Science and Technology, China (Grant No. 2021ZD0302600).

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步骤		第1步	第2步	第3步	第4步
温区A (Bi₂Se₃)	温度/℃	室温—100	100—580	580	580—室温
温区A (Bi₂Se₃)	时间/min	5	25	30	—
温区B	温度/℃	室温—100	100—610	610	610—室温
温区B	时间/min	5	30	25	—
温区C (Bi₂O₃)	温度/℃	室温—100	100—630	630	630—室温
温区C (Bi₂O₃)	时间/min	5	30	25	—

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