The reversal mechanisms in arrays of nanometer-scale (<40 nn diameter)
iron particles are studied by low-temperature Hall magnetometry and r
oom-temperature magnetic force microscopy, Rotation of the net array m
agnetization at low temperatures (20 K) occurs by both reversible and
irreversible modes, the latter revealed by Barkhausen jumps. Spatially
resolved measurements at room temperature show the particles to be si
ngle domain with remanence and coercivity indicating they are not supe
rparamagnetic. Individual particles are observed to switch irreversibl
y over a small field ranee (<10 Oe) between preferred magnetic directi
ons parallel to the growth direction of the particles. Scaling of the
arrays offers the possibility of magnetic storage at the 45 Gbit/in.(2
) level, nearly 50 times greater than current technology. (C) 1996 Ame
rican Institute of Physics.