The elusive ε-Fe2O3 has been obtained as nanoparticles by vacuum heat treatment of yttrium iron
garnet in a silica matrix at 300 °C followed by annealing at 1000 °C for up to 10 h in air and employing
formamide as a gel modifier. Its nuclear structure is temperature independent as observed from the neutron
powder diffraction patterns and has been modeled by the published structures on analogous MM‘O3
compounds. It displays complex magnetic properties that are characterized by two transitions: one at
480 K from a paramagnet (P) to canted antiferromagnet (CAF1) and the second at ca. 110 K from the
canted antiferromagnet (CAF1) to another canted antiferromagnet (CAF2) that has a smaller resultant
magnetic moment (i.e., smaller canting angle). The latter transition resembles that of Morin for α-Fe2O3
at 260 K. The magnetization shows unusual history dependence: it has a bifurcation below 100 K if the
field is applied at low temperatures after zero-field-cooled, whereas the bifurcation is above 150 K if the
field is applied at high temperatures. The magnetic hardness first increases slightly from 300 to 200 K,
then it drastically decreases to zero at 100 K and follows a further increase down to 2 K. The coercive
field reaches an unexpected and quite exceptional 22 kOe at 200 K. There appears to be a further ill-defined metamagnetic transition below 50 K, characterized by a doubling of the measured magnetization
in 50 kOe. The AF1−AF2 transition is accompanied by sharp peaks in both the real and imaginary
components of the ac-susceptibility due to the hard−soft effect, and their peak maxima shift to lower
temperatures on increasing the frequency. Mössbauer spectra are characterized by a change in hyperfine
field of the tetrahedral Fe by ca. 40% around the transition, suggesting a change of geometry.
Unusually high magnetic hardness, characterized by a coercive field of 2 T at 2 K, has been observed for 12 nm particles of CoFe2O4 (15%) in amorphous silica prepared by the sol–gel technique and sintered at 1000 °C. Field‐ and temperature‐dependence magnetization data (see Figure) for these particles and those of 3.2 nm suggest that dipolar interaction between particles is responsible for this enhancement.
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