Z. A. Isakhanov, B. E. Umirzakov, D. Kh. Nabiev, G. T. Imanova, I. R. Bekpulatov, F. Ya. Khudaykulov, S. S. Iskhakova, Kh. E. Abdiyev
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引用次数: 0
摘要
本文首次利用高剂量植入 O2+ 离子的方法,在 W(111) 的表面和不同深度获得了纳米尺寸的 WO3 薄膜。研究证实,在室温下以低能量将 O2+ 离子植入 W 时,会形成部分氧化物,如 WO、WO2、WO3 和 WO4。实验证明,为了获得均匀和良好的 W 氧化物化学计量,必须在一定温度下进行氧化。确定了在钨的近表面区域获得隐藏氧化层的最佳模式、基底温度 W、O2+ 离子的能量和剂量。研究了三层 W-WO3-W(111)体系中深度分布的 O 原子浓度曲线。利用扫描电子显微镜测定了 WO3 层的形成深度和厚度。WO3 薄膜是多晶体的。所制备的薄膜具有制造薄膜 OLED 显示器和纳米薄膜 MOS 晶体管的潜力。
Influence of implantation of O2+ ions on the composition and electronic structure of the W(111) surface
In this paper, using high-dose implantation of O2+ ions, nano-sized WO3 films were obtained on the surface and at various depths of W(111) for the first time. It has been confirmed that when O2+ ions are implanted into W at room temperature with low energy, partial formation of oxides such as WO, WO2, WO3 and WO4 occurs. It has been proved that in order to obtain a homogeneous and good stoichiometry of W oxide, it is necessary to carry out oxidation at a certain temperature. The optimal modes for obtaining hidden oxide layers in the near-surface region of tungsten, the substrate temperature W, the energy and dose of O2+ ions were determined. The concentration profiles of distributed O atoms in depth were studied for the three-layer W-WO3-W(111) system. Using scanning electron microscopy, the formation depths and thicknesses of WO3 layers were determined. The WO3 films were polycrystalline. The resulting films have potential for creating thin-film OLED displays, as well as nanofilm MOS transistors.
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