Magnetic Force Microscopy of Magnetite Thin Films with Transition Metal Buffer Layers

Alfred KH. Lee; Mark C. Monti; John T. Markert; Alex de Lozanne; Priyanga B. Jayathilaka; Chris A. Bauer; Casey W. Miller

Magnetic Force Microscopy of Magnetite Thin Films with Transition Metal Buffer Layers

ORAL

Abstract

Magnetite (Fe$_{3}$O$_{4}$) has been the subject of interest as a material for use in spin devices. Its ideal properties for this application break down in thin film morphologies due to the occurrence of antiphase boundaries (APBs). The density of APBs can be adjusted to some degree via film strain. This is accomplished in this work by including a variety of transition metal buffer layers between Fe$_{3}$O$_{4}$ and its MgO substrate. We investigate the microscale magnetic domain structure via magnetic force microscopy of Fe$_{3}$O$_{4}$ films on MgO with no, a Mo, or an Fe buffer layer across a temperature range surrounding the Verwey temperature (T$_V \sim$ 120K) and compare to bulk measurements from a SQUID magnetometer.

^*Supported by NSF-ECCS (USF), NSF-DMR (UT), NSF-IGERT (UT), and the Welch Foundation (UT).

March 22, 2011, 3:54 PM – March 22, 2011, 4:06 PM

Authors

Alfred KH. Lee
- Department of Physics, The University of Texas at Austin
Mark C. Monti
- Department of Physics, The University of Texas at Austin
John T. Markert
- Department of Physics, The University of Texas at Austin
Alex de Lozanne
- Department of Physics, The University of Texas at Austin
Priyanga B. Jayathilaka
- Physics Department, University of South Florida
Chris A. Bauer
- Physics Department, University of South Florida
Casey W. Miller
- Physics Department, University of South Florida