Energy Materials and Convergence Research Department, Korea Institute of Energy Research, 71-2 Jang-dong, Yuseong-gu, Daejeon, Korea.
Nanotechnology. 2012 Jul 20;23(28):285604. doi: 10.1088/0957-4484/23/28/285604. Epub 2012 Jun 25.
We demonstrate a simple and reproducible technique to synthesize crystalline and superconducting In-Sn intermetallic nanowires sheathed in carbon nanotubes (CNTs). The method is based on the catalytic reaction of C(2)H(2) over a mixture of both SnO(2) and In(2)O(3) particles. Importantly, tetragonal β-In(3)Sn and hexagonal γ-InSn(4) nanowires with diameters of less than 100 nm are selectively synthesized at different SnO(2) to In(2)O(3) weight ratios. CNTs may serve as cylindrical nanocontainers for continuous growth of liquid-phased In(1-x)Sn(x) nanowires during growth process as well as for their solidification into In-Sn intermetallic nanowires during the cooling process. Microscopic and spectroscopic analyses clearly reveal evidence of a core-shell structure of the CNT-sheathed In-Sn intermetallic nanowires. Magnetization measurements show that the superconducting In-Sn nanowires have a critical magnetic field higher than the value of their bulk intermetallic compounds. Our method can be adopted to the nanofabrication of analogous binary and ternary alloys.
我们展示了一种简单且可重现的技术,用于合成包覆在碳纳米管(CNT)中的结晶和超导 In-Sn 金属间化合物纳米线。该方法基于 C(2)H(2)在 SnO(2)和 In(2)O(3)颗粒混合物上的催化反应。重要的是,在不同的 SnO(2)与 In(2)O(3)重量比下,可选择性地合成直径小于 100nm 的四方β-In(3)Sn 和六方γ-InSn(4)纳米线。CNT 可作为圆柱形纳米容器,用于在生长过程中连续生长液态 In(1-x)Sn(x)纳米线,并在冷却过程中将其固化为 In-Sn 金属间化合物纳米线。微观和光谱分析清楚地表明了 CNT 包覆的 In-Sn 金属间化合物纳米线具有核壳结构的证据。磁化测量表明,超导 In-Sn 纳米线的临界磁场高于其体相金属间化合物的数值。我们的方法可应用于类似二元和三元合金的纳米制造。
