高压梯度下Fe-Ag和Fe-Cu的冷烧结固结

Альфия Фаритовна Шарипова, Сергей Григорьевич Псахье, И. Готман, М. И. Лернер, А. С. Ложкомоев, Э. Ю. Гутманас
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摘要

本文介绍了高压梯度冷烧结固结复合粉末以及银(Ag)、铁(Fe)和铜(Cu)纳米粉末制备Fe - Ag和Fe - Cu致密纳米复合材料的研究结果。给出了Fe-Ag和Fe-Cu纳米复合材料的力学性能测试结果。将羰基铁(Fe)微米级粉末和纳米氧化银粉(Ag2O)以及铁和氧化亚铜(Cu2O)纳米粉末进行高能磨粉制备纳米复合粉体。采用高分辨率扫描电镜对其微观结构进行了研究。在氢气气氛中退火具有约70%全密度的压块,以将银和亚铜氧化物还原为金属并去除铁粉颗粒表面的氧化层。接着是冷烧结——在室温下高压下的固结。得到了在0,25 - 3,0 GPa范围内试样密度随压力变化的数据。所有纳米复合材料的密度都在满密度的95%以上,Ag和Cu粉末在3.0 GPa下的密度接近满密度的100%。所有纳米复合材料在三点弯曲和三点压缩时均具有较高的力学性能。结果表明,纳米复合材料的力学性能明显高于微米级粉末复合材料。Fe - ag和Fe - cu纳米复合材料的延展性比Fe纳米复合材料高。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Cold sintering of Fe-Ag and Fe-Cu by consolidation in high pressure gradient
The paper states the results of obtaining Fe—Ag and Fe—Cu dense nanocomposites from composite powders consolidated by cold sintering in the high pressure gradient, as well as from nanosize powders of silver (Ag), iron (Fe) and copper (Cu). The results of mechanical tests conducted on Fe—Ag and Fe—Cu nanocomposites are provided. Nanocomposite powders were obtained by high energy attrition milling of carbonyl iron (Fe) micron scale powder and nanosize silver oxide powder (Ag2O), as well as iron and cuprous oxide (Cu2O) nanopowders. High resolution scanning electron microscopy was used to study the microstructure. Compacts featuring approximately 70 % of full density were annealed in hydrogen atmosphere to reduce silver and cuprous oxides to metals and to remove oxide layers from the surface of iron powder particles. This was followed by cold sintering — consolidation under high pressure at a room temperature. The data on specimen density dependence on pressure in the range of 0,25 —3,0 GPa were obtained. Densities were above 95 % of the full density for all nanocomposites, and close to 100 % of the full density under 3,0 GPa for Ag and Cu powders. High mechanical properties in three-point bending and compression were observed for all nanocomposites. It was found that mechanical properties of nanocomposites are substantially higher as compared with composites obtained from micron scale powders. Higher ductility was observed in Fe—Ag and Fe—Cu nanocomposites as compared with specimens obtained from nanostructured Fe.
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