Effects of Order-Disorder Reactions on the Magnetic Properties of Rapidly Quenched Fe-6.5% Si Alloy

F.A. Nascimento; M.C.A. da Silva

doi:10.4028/www.scientific.net/MSF.802.530

Paper Titles

Chemical, Structural and Mechanical Study of Metallic Biomaterials Used in Hip Arthroplasty
p.507

Characterization of Titanium Powders Processed at Different Temperatures
p.512

Microstructural Characterization of a High Copper (Nd_0.75Pr_0.25)₂Fe₁₄B Magnet
p.518

Sintered Fe50Ni Alloy Produced by Mixing Iron and Nickel Powders
p.524

Effects of Order-Disorder Reactions on the Magnetic Properties of Rapidly Quenched Fe-6.5% Si Alloy
p.530

Superparamagnetic Iron Oxide Nanoparticles for Magnetic Hipertermia: Synthesis, Surface Modification by Polyethylene Glycol and Characterization
p.535

Grain Growth Kinetics of (NdPr)₂Fe₁₄B Magnets
p.540

Influence of the Grain Size on the Dysprosium Diffusion in NdFeB Magnets
p.546

Frequency Characterization of Ferrite Beads in the Microwave Range for Nonlinear Applications
p.552

HomeMaterials Science ForumMaterials Science Forum Vol. 802Effects of Order-Disorder Reactions on the...

Effects of Order-Disorder Reactions on the Magnetic Properties of Rapidly Quenched Fe-6.5% Si Alloy

Abstract:

Deposits of the Fe-6.5wt%Si alloy rapidly quenched by spray forming were investigated. The order phase can be either B2 or DO3 depending on annealing treatment conditions. The observation of pairs dislocations indicates the presence of super dislocations and B2 antiphase boundaries (APBs) which affects significantly the soft magnetic properties. The dislocations bound the APBS which yield δ fringes when image 200 superlattice reflections. Samples treated at 700oC for 1 h were oil quenched, this has induced a decreasing of power loss and the TEM micrographs have showed developed 1⁄4 <111> antiphase domain structure in the B2 phase. The magnetic properties were: power loss of 1.59 W/kg and coercive force of 76 A/m, at B=1 T, f=60 Hz. The samples annealed at 1250°C for 1h showed the same interaction between the APBs but better power losses on their magnetic properties. The magnetic properties were: 1.30 W/kg power loss and 40 A/m coercive force, at same conditions described above. This suggests a strong interaction between magnetic properties and antiphase domain structure in the B2 ordered phase. Optical microscopy observations corroborate the magnetic measurement conclusions.