Gu Hengfei, Li Geping, Liu Chengze, Yuan Fusen, Han Fuzhou, Zhang Lifeng, Wu Songquan
Institute of Metal Research, Chinese Academy of Sciences, 72 Wenhua Road, Shenyang, 110016, People's Republic of China.
University of Chinese Academy of Sciences, 19 Yuquan Road, Beijing, 100049, People's Republic of China.
Sci Rep. 2017 Mar 15;7(1):184. doi: 10.1038/s41598-017-00251-3.
Under electron beam irradiation, knock-on atomic displacement is commonly thought to occur only when the incident electron energy is above the incident-energy threshold of the material in question. However, we report that when exposed to intense electrons at room temperature at a low incident energy of 30 keV, which is far below the theoretically predicted incident-energy threshold of zirconium, Zircaloy-4 (Zr-1.50Sn-0.25Fe-0.15Cr (wt.%)) surfaces can undergo considerable displacement damage. We demonstrate that electron beam irradiation of the bulk Zircaloy-4 surface resulted in a striking radiation effect that nanoscale precipitates within the surface layer gradually emerged and became clearly visible with increasing the irradiation time. Our transmission electron microscope (TEM) observations further reveal that electron beam irradiation of the thin-film Zircaly-4 surface caused the sputtering of surface α-Zr atoms, the nanoscale atomic restructuring in the α-Zr matrix, and the amorphization of precipitates. These results are the first direct evidences suggesting that displacement of metal atoms can be induced by a low incident electron energy below threshold. The presented way to irradiate may be extended to other materials aiming at producing appealing properties for applications in fields of nanotechnology, surface technology, and others.
在电子束辐照下,通常认为只有当入射电子能量高于相关材料的入射能量阈值时才会发生原子的碰撞位移。然而,我们报道,当在室温下以30 keV的低入射能量暴露于强电子时(该能量远低于理论预测的锆的入射能量阈值),锆合金-4(Zr-1.50Sn-0.25Fe-0.15Cr(重量百分比))表面会遭受相当大的位移损伤。我们证明,对块状锆合金-4表面进行电子束辐照会产生显著的辐射效应,即表面层内的纳米级析出物逐渐出现,并随着辐照时间的增加变得清晰可见。我们的透射电子显微镜(TEM)观察进一步表明,对薄膜锆合金-4表面进行电子束辐照会导致表面α-Zr原子的溅射、α-Zr基体中的纳米级原子重组以及析出物的非晶化。这些结果是首次直接证明低于阈值的低入射电子能量可诱导金属原子发生位移。所提出的辐照方法可能会扩展到其他材料,旨在为纳米技术、表面技术等领域的应用产生具有吸引力的性能。