Observation of an antiparallel magnetic state in $Fe3O4/Mn3O4$ superlattices

$[Fe3O4(20 Å)/Mn3O4(80 Å)]x20$ and $[Fe3O4(20 Å)/MgO(80 Å)]x20$ superlattices on MgO(001) are fabricated by molecular beam epitaxy in order to compare the magnetic coupling in ferrimagnetic–ferrimagnetic and ferrimagnetic–nonmagnetic systems. The magnetic response is measured as a function of applied-field (−50 to 50 kOe) parallel to the film surface and temperature (5–300 K). A strong reduction of magnetization, from 115 to 45 emu/cm³, is observed only from the $Fe3O4/Mn3O4$ superlattice at temperature below ∼60 K. This observation indicates that the magnetic moments in two constituents are antiparallel and the Curie temperature $(Tc)$ of $Mn3O4$ is enhanced for 15 K. In addition, the remanent magnetization shows a compensation point $(Tcp)$ at about 32 K at which the opposing spins are balanced. Detailed magnetic hysteresis loops measured at different temperature further explore magnetic phase transitions as a function of external field and temperature. A possible phase diagram is similar to the previous Gd/Fe multilayered system in that $Mn3O4$ is parallel and $Fe3O4$ antiparallel to the applied field below $Tcp$ while $Fe3O4$ is parallel and $Mn3O4$ antiparallel to the applied field above $Tcp.$ Moreover, a spin-flop-like phase is observed above a critical external field, $H*,$ ∼10 kOe.