Title :
Studies of the stoichiometrical variation of epitaxial Fe3(1-δ)O4 thin films
Author :
Lochner, E. ; Shaw, K.A. ; DiBari, R.C. ; Portwine, W. ; Stoyonov, P. ; Berry, S.D. ; Lind, D.M.
Author_Institution :
Nat. High Magnetic Field Lab., Florida State Univ., Tallahassee, FL, USA
fDate :
11/1/1994 12:00:00 AM
Abstract :
Using plasma-assisted molecular beam epitaxy, (MBE) films of iron oxide spinel phases of Fe3(1-δ)O4 type have been grown on single crystal MgO(100). Stoichiometry was controlled by variation of growth parameters, including substrate temperature, oxygen flux, plasma power, and deposition rate. Structural and magnetic studies of these films have been performed using SQUID magnetometry and X-ray diffraction (XRD), The temperature dependence of the Verwey transition, a strong indicator of iron oxide stoichiometry which occurs in Fe3 O4 at ~123 K, is broadened and pushed downward in temperature with decreasing iron content (and is absent in γ-Fe 2O3). Lattice spacing, Verwey response, and magnetic ordering show that stable growth over a broad range of conditions results in stoichiometric Fe3O4, although variation of growth parameters (especially high O2/Fe flux ratios) can produce a range of Fe3(1-δ) O4 “defect-spinels”
Keywords :
X-ray diffraction; iron compounds; magnetic epitaxial layers; magnetic thin films; metal-insulator transition; molecular beam epitaxial growth; stoichiometry; Fe3O4; MgO; O2 flux; SQUID magnetometry; Verwey transition; X-ray diffraction; deposition rate; epitaxial thin films; plasma power; plasma-assisted MBE; single crystal MgO(100); spinel phases; stoichiometry; substrate temperature; Iron; Magnetic films; Magnetic flux; Molecular beam epitaxial growth; Plasma temperature; Plasma x-ray sources; SQUIDs; Substrates; Temperature control; Temperature dependence;
Journal_Title :
Magnetics, IEEE Transactions on
