Title :
Giant magnetoresistance of melt-spun Cu-Ni-Fe alloys with spinodally-decomposed structure
Author :
Chen, L.H. ; Yang, Y.K. ; Chang, Y.H.
Author_Institution :
Dept of Mater. Eng., Kaohsiung Polytech. Inst., Taiwan
fDate :
11/1/1995 12:00:00 AM
Abstract :
We report the observation of giant magnetoresistance effect in as-spun and annealed spinodally decomposed Cu-Ni-Fe alloy ribbons. The magnetoresistance ratio of 9.5% was observed at 4.2 K for as-spun Cu70Ni15Fe15 ribbon, which could be increased to 12.0% by annealing at 400 C for 15 min. In contrast to the temperature dependence of the magnetoresistance ratio of sputtered Cu-Ni-Fe films, melt-spun Cu-Ni-Fe ribbons show an increase in the magnetoresistance ratio upon cooling from room temperature to 4.2 K. The observed giant magnetoresistance behavior in Cu-Ni-Fe ribbons is mostly caused by the spin-dependent scattering at the two-phase interface and in the ferromagnetic phase, as well as scattering due to magnetic fluctuations such as very fine ferromagnetic particles
Keywords :
annealing; copper alloys; ferromagnetic materials; giant magnetoresistance; iron alloys; magnetic particles; magnetic thin films; magnetoresistance; nickel alloys; spinodal decomposition; sputtered coatings; 15 min; 4.2 K; 400 C; Cu70Ni15Fe15; as-spun Cu70Ni15Fe15 ribbon; ferromagnetic phase; giant magnetoresistance effect; magnetic fluctuations; magnetoresistance ratio; melt-spun Cu-Ni-Fe alloys; spin-dependent scattering; spinodally-decomposed structure; two-phase interface; very fine ferromagnetic particles; Annealing; Copper alloys; Fluctuations; Giant magnetoresistance; Magnetic field measurement; Magnetic superlattices; Magnetization; Metallic superlattices; Particle scattering; Temperature dependence;
Journal_Title :
Magnetics, IEEE Transactions on
