Abstract
Mechanical alloying of two aluminum alloy powders to form composite A1-A12O3 powders has been studied. Changes in powder microstructure with processing are reported and interpreted. Mechanical alloying proceeds by the continual cold welding and fracturing of the constituent powder particles when subjected to the large compressive forces of a high speed mill. A suitable organic surfactant must be added so that a balance between cold welding and fracturing is obtained. The organic surfactant is embedded and finely distributed in the powder particles during mechanical alloying and is converted to discrete A14C3 particles after hot pressing. The establishment of steady state processing conditions, characterized by equiaxed powder particles, a constant particle size distribution and a saturation hardness, is found to depend on the size distribution of the initial powders. The oxide particles formed and distributed during mechanical alloying are equiaxed, small (30 nm) and homogeneously distributed with a volumetric center to center distance of about 60 nm.
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Formerly Graduate Research Assistant in the Department of Materials Science and Engineering at Stanford.
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Gilman, P.S., Nix, W.D. The structure and properties of aluminum alloys produced by mechanical alloying: Powder processing and resultant powder structures. Metall Trans A 12, 813–824 (1981). https://doi.org/10.1007/BF02648346
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DOI: https://doi.org/10.1007/BF02648346