Nanocomposite Formation in the Fe3O4-M (M=Al, Ti) Systems by Mechanical Alloying

Chung Hyo Lee; Seong Hee Lee; Sang Jin Lee; Yong Ho Choa; Ji Soon Kim

doi:10.4028/www.scientific.net/KEM.317-318.623

Paper Titles

Alumina-Based Nanocomposites Fabricated by a Novel Soaking Method
p.607

Properties and Microstructure of Mullite-Based Iron Nanocomposite
p.611

High-Toughness Tetragonal Zirconia/Alumina Nano-Ceramics
p.615

Microstructures and Mechanical Properties of Fine-Scale Fibrous Alumina / Zirconia Bi-Phase Composite Fabricated by Co-Extrusion Process
p.619

Nanocomposite Formation in the Fe₃O₄-M (M=Al, Ti) Systems by Mechanical Alloying
p.623

Fabrication of α-Sialon Nano-Ceramics
p.629

Fabrication and Evaluation of β-SiAlON Nanoceramics
p.633

Fabrication and Properties of Machinable AlN-BN Ceramic Nanocomposites
p.637

Electrical Properties of AlN-SiC Ceramics
p.641

HomeKey Engineering MaterialsKey Engineering Materials Vols. 317-318Nanocomposite Formation in the Fe3O4-M (M=Al, Ti)...

Nanocomposite Formation in the Fe₃O₄-M (M=Al, Ti) Systems by Mechanical Alloying

Abstract:

Nanocomposite formation of metal-metal oxide systems by mechanical alloying (MA) has been investigated at room temperature. The systems we chose are the Fe3O4-M (M=Al, Ti), where pure metals are used as a reducing agent. It is found that nanocomposite powders in which Al2O3 and TiO2 are dispersed in a α-Fe matrix with nano-sized grains are obtained by MA of Fe3O4 with Al and Ti for 25 and 75 hours, respectively. It is suggested that the shorter MA time for the nanocomposite formation in Fe3O4-Al is due to a large negative heat associated with the chemical reduction of magnetite by aluminum. X-ray diffraction results show that the average grain size of α-Fe in Fe-TiO2 nanocomposite powders is in the range of 30 nm. From magnetic measurement, we can also obtain indirect information about the details of the solid-state reduction process during MA.