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MA: Magnetismus
MA 20: Poster:Schichten(1-29),Spintrsp(30-45),Ex-Bias(46-63),Spindyn(64-75),Mikromat.(76-80),Cluster(81-94),Abbv.(95-99),Obflm(100-02),SpElek.(103-09),E-Theo(110-14),Mikromag.(115-16),Spin+PÜ(117-26),Mag.Mat.(127-51),Meth.(152-55),Mol.Mag(156-59),Kondo(160-65
MA 20.37: Poster
Montag, 7. März 2005, 14:00–18:00, Poster TU C
Large room temperature TMR effect in Fe3O4 based magnetic tunnel junctions — •Edwin Menzel, Suleman Qureshi, Daniel Reisinger, Andreas Erb, Matthias Opel, and Rudolf Gross — Walther-Meißner-Institut, Bayerische Akademie der Wissenschaften, Walther-Meißner-Str. 8, 85748 Garching
Magnetite (Fe3O4) is an interesting candidate for
applications in spin electronics. It shows a Curie temperature of 860 K and
has
been predicted to be half-metallic at room temperature [1]. We have
fabricated
Fe3O4/oxide/FM (FM = Ni, Co, Fe3O4) trilayer structures using
pulsed laser deposition and electron beam evaporation. The thin film stacks
have been studied by in-situ RHEED, SQUID magnetometry, and high-resolution
X-ray diffraction. Magnetic tunnel junctions have been fabricated using
optical
lithography and Ar ion beam milling. The junctions have been characterized
by
magnetotransport measurements between 150 K and 350 K. They show a
reproducible
tunneling magnetoresistance (TMR) effect with almost ideal switching
behavior.
We obtain TMR values of up to 20% for Fe3O4/AlOx/Co and
Fe3O4/AlOx/Ni at room temperature. We also found a geometry
enhanced
TMR effect due to an inhomogeneous current distribution in the junction
electrodes. This effect has been modeled by finite element methods. We find
that the geometry enhanced TMR effect can be optimized by adjusting the
junction geometry and the electrode resistivity. In our experiments,
reproducible TMR effects exceeding 1000% at room temperature have been
found.
This work is supported by the BMBF via grant no. 13N8279.
[1] Z. Zhang, and S. Satpathy, Phys. Rev. B, 44, 13319 (1991).