A novel nanostructured sandwich PAA/Al/PAA (PAA: porous anodic alumina) was successfully designed and fabricated by anodic oxidation on both sides of an Al foil. The pore size of the PAA membranes was controlled by choosing appropriate voltage, length of anodic oxidization time, temperature and electrolytes. The thickness of the central Al layer was varied by changing the anodic oxidization time. We show that the nanostructured sandwich PAA/Al/PAA can be used as a template in fabricating homogeneous or heterogeneous nanostructured sandwiches by depositing the same kind of material or different materials into the PAA membranes of the sandwich. We also show that it can be used to prepare nanowires and bipolar electrodes. In addition. Al nanosheets or Al nanowalls were produced by removing the PAA films completely or partially. Nanogaps between the PAA films were also formed by etching away the centre Al layer of the sandwich structures. The thickness of these nanosheets, nanowalls and nanogaps was controlled by choosing appropriate electrolytes and electrochemical parameters during the anodic oxidation of Al. All these nanostructures offer novel opportunities for both fundamental research and technological applications of low dimensional nanostructure systems.
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机译:通过在铝箔的两面进行阳极氧化,成功设计和制造了一种新型的纳米结构三明治PAA / Al / PAA(PAA:多孔阳极氧化铝)。通过选择合适的电压,阳极氧化时间,温度和电解质来控制PAA膜的孔径。通过改变阳极氧化时间来改变中央Al层的厚度。我们表明,通过将相同类型或不同种类的材料沉积到三明治的PAA膜中,纳米结构的三明治PAA / Al / PAA可以用作制造均质或非均质纳米结构三明治的模板。我们还表明,它可用于制备纳米线和双极电极。此外。通过完全或部分去除PAA膜来制备Al纳米片或Al纳米壁。通过蚀刻掉夹层结构的中心Al层,也形成了PAA膜之间的纳米间隙。通过在铝的阳极氧化过程中选择合适的电解质和电化学参数来控制这些纳米片,纳米壁和纳米间隙的厚度。所有这些纳米结构为低维纳米结构系统的基础研究和技术应用提供了新的机遇。
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