Shenyang National Laboratory for Materials Science, Institute of Metal Research, Chinese Academy of Sciences, Shenyang 110016, China.
Science. 2013 Oct 18;342(6156):337-40. doi: 10.1126/science.1242578.
Heavy plastic deformation may refine grains of metals and make them very strong. But the strain-induced refinement saturates at large strains, forming three-dimensional ultrafine-grained (3D UFG) structures with random orientations. Further refinement of this microstructure is limited because of the enhanced mobility of grain boundaries. Very-high-rate shear deformation with high strain gradients was applied in the top surface layer of bulk nickel, where a 2D nanometer-scale laminated structure was induced. The strongly textured nanolaminated structure (average lamellar thickness of 20 nanometers) with low-angle boundaries among the lamellae is ultrahard and ultrastable: It exhibits a hardness of 6.4 gigapascal--which is higher than any reported hardness of the UFG nickel--and a coarsening temperature of 40 kelvin above that in UFG nickel.
剧烈塑性变形可以细化金属晶粒并使其非常强。但是应变诱导的细化在大应变时会达到饱和,形成具有随机取向的三维超细晶(3D UFG)结构。由于晶界迁移率的提高,这种微观结构的进一步细化受到限制。采用高应变速率和高应变梯度的剪切变形在块状镍的顶层表面进行,在那里诱导出二维纳米级层状结构。具有强烈织构的纳米层状结构(层间的平均层厚为 20 纳米)和层间的小角度晶界非常坚硬且稳定:它表现出 6.4 吉帕斯卡的硬度——高于任何报道的 UFG 镍的硬度——以及高于 UFG 镍的粗化温度 40 开尔文。