Mechanically driven alloying of immiscible elements
- 6 April 1992
- journal article
- research article
- Published by American Physical Society (APS) in Physical Review Letters
- Vol. 68 (14) , 2235-2238
- https://doi.org/10.1103/physrevlett.68.2235
Abstract
We report on the formation by mechanical alloying of fcc solid solution of Fe and Cu, which are immiscible. Intense codeformation of Cu with Fe and other high-melting bcc metals generates small fragments with tip radii of the order 1 nm such that capillary pressures force the atoms on these fragments to dissolve. The critical radius for dissolution is found to increase with solute content inside the spinodal thus leading to full dissolution of one of the components. The fcc-FeCu solid solutions have Curie temperatures similar to those of vapor-deposited alloys and a positive heat of mixing that is in accord with theoretical results.Keywords
This publication has 15 references indexed in Scilit:
- Ordering and Disordering in AlloysPublished by Springer Nature ,1992
- Amorphization of CuTa alloys by mechanical alloyingMaterials Science and Engineering: A, 1991
- Metastable phase transformations induced by ball-milling in the CuW systemMaterials Science and Engineering: A, 1991
- Amorphization in an immiscible CuV system by mechanical alloying and structure observed by neutron diffractionMaterials Science and Engineering: A, 1991
- Thermodynamic and kinetic justification for amorphization by mechanical alloying ofA-Bmetal couples with zero heat of mixing ΔPhysical Review Letters, 1990
- Suppression of crystal nucleation in amorphous layers with sharp concentration gradientsPhysical Review Letters, 1990
- A transient nucleation model for solid state amorphisationMaterials Letters, 1988
- Thermodynamic analysis of concentration fluctuations and homogeneous nucleation of crystal in undercooled liquid binary alloys: Application to glass forming abilityJournal of Materials Science, 1987
- Coupled phase diagrams and thermochemical data for transition metal binary systems-IIICalphad, 1978
- The surface tension in a structural model for the solid-liquid interfaceScripta Metallurgica, 1976