Abstract
Nanostructured disordered iron–aluminium–copper alloy of Fe–30% Al–20% Cu composition was prepared by mechanical alloying of the elemental powders in a high-energy ball mill. The transformations occurring in the material during milling were studied with the use of X-ray diffraction. The transformation of the phase depends upon the milling time. With the increase of milling time all Al and Cu atoms became dissolved in the bcc Fe and the final product of the MA process was the nanocrystalline Fe(Al,Cu) solid solution with a mean crystallite size of about 9nm. Scanning electron microscopy (SEM) was employed to examine the morphology of the samples as a function of milling times. Magnetic properties were also investigated and were related to the microstructural changes. The unprocessed sample showed a soft ferromagnetic behavior (Hc≈173A/m) whereas alloyed samples at the early stages of processing reached a hardening ferromagnetic behavior (Hc≈15277A/m). For longer milling time the magnetic behavior slightly softened becoming a semihard ferromagnetic (Hc≈5500A/m).
Observed (points) and calculated (solid line) room temperature X-ray diffraction patterns of BCC (110) peak for (a) 2h, (b) 4h (c) 6h, and (d) 10h. The observed–calculated difference pattern is depicted at the bottom of each figure. [Display omitted]
•It is a complete study about the alloying process of a Fe–Al–Cu alloy.•Nanocrystalline (9nm) Fe(Al,Cu) solid solution is formed.•We establish the relations between microstructure and magnetic behavior.•Mechanical alloying affects positively the transition towards the magnetism hardening.