We clarified the mechanism of thermal deterioration that occurs in the CoFe
B/PdPtMn spin-valve films at temperatures above 310 degrees C. Two kinds of
CoFeB spin-valve film, Ta/NiFe/CoFeB/Cu/CoFeB/PdPtMn/Ta (B:0-3 at. %) and
Ta/NiFe/CoFeB/Cu/CoFeB/FeMn/Ta (B:2 at. %), were prepared and annealed in a
magnetic field. For the PdPtMn spin-valve samples, the magnetoresistance (
MR) output decreased after annealing at a temperature above 330 degrees C a
nd there was an increase in the interlayer coupling field of free and pin l
ayers (Hin). There was no large change in the sheet resistance for annealin
g below 330 degrees C. For CoFe/PdPtMn(no B) spin valves, the MR output dec
reased during annealing at more than 310 degrees C and there was an increas
e of Hin. An addition of only 1 at. % of boron into the free and pinned lay
ers is sufficient to obtain thermal stability. For the CoFeB/FeMn spin-valv
e samples, the MR output decreased for annealing above 280 degrees, the she
et resistance increased, and the Hin value did not change for annealing bel
ow 300 degrees C. The interface properties of PdPtMn spin valves were exami
ned using high resolution scanning transmission electron microscopy with en
ergy dispersive spectroscopy. We observed the connection between the free a
nd the pinned layers through Cu pinholes and reduced Mn inter diffusion for
the deteriorated sample. The increase of Hin can be explained by the pinho
les of the Cu layer which result in a connection between the free and pinne
d layers. Boron in the free and pinned layer has the effect of blocking dif
fusion, thereby preventing a connection of the free and pinned layers. (C)
1999 American Institute of Physics. [S0021-8979(99)35508-0].