The magnetization of cubic Zn1-xFexSe, with x=0.003 and 0.007, was mea
sured at temperatures 2 less-than-or-equal-to T less than or similar t
o 50 K in magnetic fields H along the [100] and [111] directions. Data
for H less-than-or-equal-to 55 kOe were taken with a superconducting
quantum interference device magnetometer. Other data in fields up to 2
00 kOe were taken with a vibrating sample magnetometer operating in a
Bitter magnet. At the lowest temperatures the magnetization M at high
magnetic fields is anisotropic: at a given T and for the same magnitud
e H of the magnetic field, M for H\\[100] is larger than for H\\[111].
The difference between the values of M for these directions reaches a
maximum value of 19% at the lowest temperatures and when H congruent-
to 150 kOe. As the temperature rises, the anisotropy of the high-field
magnetization decreases gradually, becoming very small above 40 K. In
low fields (H less than or similar to 10 kOe) the anisotropy is very
small at all temperatures. These experimental results are generally in
good agreement with theoretical calculations based on crystal field t
heory and on the assumption that only isolated Fe++ ions (singles) con
tribute to the magnetization. Minor discrepancies between experiment a
nd theory remain, however.