The insulating nature
and the low intrinsic damping of rare earth
iron garnets made them the material of choice for spintronic research.
While yttrium iron garnet (YIG) thin films are well studied and especially
known for their ultralow Gilbert damping parameter, recently other
rare earth iron garnet (RIG) thin films with more complex magnetic
structures have gained interest. Tunable magnetic properties like
the magnetic compensation temperature or perpendicular magnetic anisotropy
(PMA) are hereby of great interest for the implementation in spintronic
devices. In this regard, calculations predict PMA which can be induced
by magnetoelastic anisotropy for the RIGs, depending on the substrate
choice and subsequent film strain. We have therefore investigated
the influence of lattice mismatch provided by various garnet substrates
and film stoichiometry on the structural and magnetic properties of
gadolinium iron garnet (GdIG) thin films with thicknesses between
13 and 218 nm. Epitaxial, single-crystalline films exhibiting smooth
interfaces were prepared by pulsed laser deposition at elevated temperatures.
PMA is obtained for GdIG thin films grown under tensile in-plane strain
on Gd3Sc2Ga3O12 (GSGG)
substrates. Furthermore, a thickness series reveals a slow structural
relaxation and PMA even for 218 nm thick GdIG films. In contrast,
slightly off-stoichiometric films show a reduction or even loss in
PMA. All GdIG films exhibit a magnetic compensation point in the range
between 210–260 K, which is lower than for bulk (286 K). In
addition, a temperature dependent spin reorientation transition was
observed for GdIG/GSGG samples. Therefore, GdIG films provide tunable
magnetic properties controllable by film strain, stoichiometry, and
temperature, which will be beneficial for further research in the
related fields of magnonics and spintronics.
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