An x-ray powder diffraction method was used to determine the location of tantalum atoms in Ni_3Al. A series of Ni_3(Al, Ta) alloys were produced with tantalum contents ranging from 0.1 to 3.0 at.%. Fine powders with average particle sizes less than 80 μ m were made from melt-spun ribbons by a grinding process. The values of the intensity of the (100) superlattice peak normalized to that of the (200) fundamental peak as a function of tantalum content agreed with the calculated values, assuming that tantalum atoms substitute on aluminum sites, not on nickel sites, and also assuming small amounts of anti-site defects exist in the ordered fee structure of Ni_3(Al, Ta) alloys. It is concluded from our experiments that tantalum atoms substitute for aluminum in Ni_3Al. The long-range order parameters thus calculated of the Ni_3(Al, Ta) alloys are generally above 0.84 and below 0.95, except for Ni_75Al_24.8Ta_0.2, at which composition the long-range order parameter is close to unity.
[1]
David P. Pope,et al.
A theory of the anomalous yield behavior in L12 ordered alloys
,
1984
.
[2]
Tomoo Suzuki,et al.
Alloying behaviour of Ni3Al, Ni3Ga, Ni3Si and Ni3Ge
,
1984
.
[3]
D. Pope,et al.
The temperature dependence of the long‐range order parameter of Ni3Al
,
1977
.
[4]
O. Izumi,et al.
Defect Structures and Long‐Range‐Order Parameters in Off‐Stoichiometric Ni3Al
,
1975
.
[5]
J. Drijver,et al.
MOSSBAUER-EFFECT MEASUREMENTS ON INTERMETALLIC COMPOUNDS NI3AL AND NI3GA
,
1973
.
[6]
B. Cullity,et al.
Elements of X-ray diffraction
,
1957
.
[7]
C. T. Liu,et al.
High-temperature ordered intermetallic alloys
,
1985
.
[8]
G. D. Rieck,et al.
International tables for X-ray crystallography
,
1962
.