Thin magnetite (Fe304) films and Fe304/MgO multilayers have been epitaxially grown by Molecular Beam Epitaxy (MBE) on MgO(100) and MgA12O4(100) substrates. The epi taxial growth on MgO(100) substrates, with a slightly larger bulk lattice parameter than that of magnetite, resulted in an in-plane expansion of the magnetite lattice, accompanied by a perpendicular compression. For films grown on MgAlsO4(100), with a smaller lattice parameter, the substrate misfit is relaxed by the incorporation of misfit dislocations at the interface. It is shown that the substrates have a large effect on the magnetic and electronic properties of the films. The characteristic Verwey transition is shifted towards lower temperatures, broadened, and reduced in amp...
Fe3O4 is a candidate material for future spintronic device applications due to its predicted half me...
Fe3O4 thin films with a thickness of about 140 nm have been deposited on MgO ~001! substrates by rea...
We report results on epitaxial magnetite (Fe3O4) thin films grown by electron beam ablation on (1 0 ...
Thin magnetite (Fe304) films and Fe304/MgO multilayers have been epitaxially grown by Molecular Beam...
Thin magnetite (Fe304) films and Fe304/MgO multilayers have been epitaxially grown by Molecular Beam...
Thin magnetite (Fe304) films and Fe304/MgO multilayers have been epitaxially grown by Molecular Beam...
Thin magnetite (Fe304) films and Fe304/MgO multilayers have been epitaxially grown by Molecular Beam...
We have carried out a systematic experimental investigation to address the question why thin films o...
Strain relaxation studies in epitaxial magnetite, Fe3O4, thin films grown on MgAl2O4(100) substrates...
This work describes the synthesis of high quality of epitaxial Fe3O4 ultrathin films and characteriz...
This work describes the synthesis of high quality of epitaxial Fe3O4 ultrathin films and characteriz...
We have systematically studied the evolution of magnetic properties, especially the coercivity and t...
THESIS 8224The strain relaxation and magneto transport properties of epitaxial magnetite (Fe3O4) thi...
We have systematically studied the evolution of magnetic properties, especially the coercivity and t...
Strain relaxation studies in epitaxial magnetite (Fe3O4) thin films grown on MgO (100) substrates us...
Fe3O4 is a candidate material for future spintronic device applications due to its predicted half me...
Fe3O4 thin films with a thickness of about 140 nm have been deposited on MgO ~001! substrates by rea...
We report results on epitaxial magnetite (Fe3O4) thin films grown by electron beam ablation on (1 0 ...
Thin magnetite (Fe304) films and Fe304/MgO multilayers have been epitaxially grown by Molecular Beam...
Thin magnetite (Fe304) films and Fe304/MgO multilayers have been epitaxially grown by Molecular Beam...
Thin magnetite (Fe304) films and Fe304/MgO multilayers have been epitaxially grown by Molecular Beam...
Thin magnetite (Fe304) films and Fe304/MgO multilayers have been epitaxially grown by Molecular Beam...
We have carried out a systematic experimental investigation to address the question why thin films o...
Strain relaxation studies in epitaxial magnetite, Fe3O4, thin films grown on MgAl2O4(100) substrates...
This work describes the synthesis of high quality of epitaxial Fe3O4 ultrathin films and characteriz...
This work describes the synthesis of high quality of epitaxial Fe3O4 ultrathin films and characteriz...
We have systematically studied the evolution of magnetic properties, especially the coercivity and t...
THESIS 8224The strain relaxation and magneto transport properties of epitaxial magnetite (Fe3O4) thi...
We have systematically studied the evolution of magnetic properties, especially the coercivity and t...
Strain relaxation studies in epitaxial magnetite (Fe3O4) thin films grown on MgO (100) substrates us...
Fe3O4 is a candidate material for future spintronic device applications due to its predicted half me...
Fe3O4 thin films with a thickness of about 140 nm have been deposited on MgO ~001! substrates by rea...
We report results on epitaxial magnetite (Fe3O4) thin films grown by electron beam ablation on (1 0 ...
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