A. Inoue et al., EFFECT OF CU OR AG ON THE FORMATION OF COEXISTENT NANOSCALE AL PARTICLES IN AL-NI-M-CE (M=CU OR AG) AMORPHOUS-ALLOYS, Materials transactions, JIM, 35(2), 1994, pp. 95-102
The precipitation of a primary Al phase upon annealing of amorphous Al
87Ni10Ce3, Al87Ni7Cu3Ce3 and Al87Ni8Ag2Ce3 alloys was found to occur o
nly through a growth mechanism, based on the result that the exothermi
c reaction due to the precipitation of Al phase on the DSC curve does
not have an incubation stage. The activation energy for the growth of
the Al phase decreases from 1.82 eV for the Al-Ni-Ce alloy to 1.44 to
1.56 eV for the Al-Ni-M-Ce (M = Cu or Ag) alloys and the annealing tem
perature and time regions where the Al phase grows extend by the repla
cement of M for Ni. The particle size of the Al phase decreases from 9
nm for the ternary alloy to 3 to 5 nm for the quaternary alloys, acco
mpanying the significant increase in the number of the Al particles. T
he extremely fine mixed structure consisting of nanoscale Al particles
embedded in the amorphous matrix is formed in the Al-Ni-M-Ce alloys c
ontaining Cu or Ag elements which are soluble to the Al phase. The for
mation of the mixed structure is presumably due to the combination of
(1) the necessity of the redistribution of the M elements for the grow
th of the Al particles resulting from the difference between the solub
le content of the M elements into the Al particles and the nominal M c
ontent in the amorphous matrix, and (2) the increase in the number of
the pre-existing nuclei of Al-rich zone resulting from the increase in
the apparent Al content caused by the replacement of Ni by the M elem
ents. The finding of the M elements leading to the refinement of the n
anoscale Al particles is important in the subsequent development of th
e nanoscale mixed phase alloys.