Ball Milling and Consolidation Process of Al-Cr Powder Mixture—Microstructural Characterization

The interest in studying the synthesis of an Al–Cr alloy system by non-equilibria processes is due to the formation of metastable or quasicrystalline phases when rapid solidification has been utilized. Similarly, the formation of quasicrystals has been reported to a much lesser extent when the mecha...

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Bibliographic Details
Published inApplied sciences Vol. 13; no. 10; p. 5976
Main Authors Rodríguez-Díaz, Roberto Ademar, Porcayo-Calderón, Jesús, Barragán, José Luis Reyes, Arrieta-González, Cinthya Dinorah, Gomez-Guzman, Néstor Belisario, Plasencia González, Iván Daniel
Format Journal Article
LanguageEnglish
Published Basel MDPI AG 01.05.2023
Subjects
al alloy
Alloy systems
Alloys
Aluminum alloys
Analysis
Ball milling
Chromium alloys
Chromium base alloys
Consolidation
Corrosion resistance
Crystallites
Crystals
Dislocation density
Ductility
Grain boundaries
Grain size
Hot pressing
Mechanical alloying
mechanical milling
Mechanical properties
Metals
Mixtures
Multiplication
nanocomposite
nanostructured alloy
Particle size
Phase transitions
Powder metallurgy
Powders
Process controls
Scanning electron microscopy
Sintering
Sintering (powder metallurgy)
solid solution
Temperature
X-ray diffraction
Mexico
United Kingdom
Germany
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Summary:The interest in studying the synthesis of an Al–Cr alloy system by non-equilibria processes is due to the formation of metastable or quasicrystalline phases when rapid solidification has been utilized. Similarly, the formation of quasicrystals has been reported to a much lesser extent when the mechanical alloying technique was applied. In the present research, a mixture of powders of Cr and Al (both elements with a purity of 99.99%) with compositions of Al-5 and 7.5 at. % Cr was subjected to a ball milling process. Afterwards, the powder mixture was subjected to a consolidation process, conducted by pressing and sintering processes. The X-ray diffraction analyses revealed that during 20 h of milling there was no formation of metastable or quasicrystalline second phases detected. In addition, the X-ray diffraction peaks revealed that as milling time increased, the nanometric grain size decreased, and once the sintering treatment was applied, the crystallite size decreased following the same tendency. The dislocation density was estimated using the size of nanometric grains; this computation revealed that the dislocation density grew throughout the ball milling process; even after sintering, the multiplication of dislocations prevailed following the same tendency.
ISSN:2076-3417
2076-3417
DOI:10.3390/app13105976