Spin-valve giant magnetoresistance films with antiferromagnetic PtPdMn

The antiferromagnetic alloy Pt20Pd30Mn50 has demonstrated a high exchange c oupling field to a coupled NiFe film as well as high corrosion resistance, making it a promising candidate for use as the pinning layer of a spin valv e. In this work we have investigated the magnetic and structural properties of spin-valve films exchange biased by CoFe/PtPdMn as compared to CoFe/IrM n spin valves. A spin-valve film structure of Ta50 Angstrom/NiFe50 Angstrom /CoFe20 Angstrom/Cu28 Angstrom/CoFe22 Angstrom/PtPdMn300 Angstrom/Ta50 Angs trom annealed at 250 degrees C for 10 h showed a giant magnetoresistance of 6.5% with an exchange field of 680 Oe. The blocking temperature of this fi lm is about 350 degrees C, compared to 250 degrees C for IrMn based spin va lves. The remnant blocking temperature was also measured, and showed that f or PtPdMn spin valves the exchange field was constant up to a temperature o f 300 degrees C, in contrast to 180 degrees C for an IrMn spin valve. Struc tural ordering of the PtPdMn in a face-centered-tetragonal (fct) phase afte r annealing has been observed using x-ray diffraction and transmission elec tron microscopy. The x-ray diffraction data exhibits a strong face-centered -cubic (111) and fct (111) out-of-plane orientation for as-deposited and an nealed samples. Transmission electron micrographs show a smooth interface b etween the PtPdMn and CoFe layers, columnar growth structure, and fct order ing of the PtPdMn. (C) 1999 American Institute of Physics. [S0021-8979(99)7 3508-5].