2006 APS March Meeting
Monday–Friday, March 13–17, 2006;
Baltimore, MD
Session Y4: High TMR MgO Tunneling and Spin Momentum Transfer Materials, Physics, and Devices
8:00 AM–11:00 AM,
Friday, March 17, 2006
Baltimore Convention Center
Room: 308
Sponsoring
Unit:
GMAG
Chair: Robert Buhrman, Cornell University
Abstract ID: BAPS.2006.MAR.Y4.1
Abstract: Y4.00001 : Giant tunneling magnetoresistance and tunneling spin polarization in magnetic tunnel junctions with MgO (100) tunnel barriers
8:00 AM–8:36 AM
Preview Abstract
Abstract
Author:
Stuart Parkin
(IBM Almaden Research Center)
Recent advances in generating, manipulating and detecting spin-polarized
electrons and electrical current make possible new classes of spin based
sensor, memory and logic devices [1]. One key component of many such devices
is the magnetic tunneling junction (MTJ) - a sandwich of thin layers of
metallic ferromagnetic electrodes separated by a tunneling barrier,
typically an oxide material only a few atoms thick. The magnitude of the
tunneling current passing through the barrier can be adjusted by varying the
relative magnetic orientation of the adjacent ferromagnetic layers. As a
result, MTJs can be used to sense the magnitude of magnetic fields or to
store information. The electronic structure of the ferromagnet together with
that of the insulator determines the spin polarization of the current
through an MTJ -- the ratio of 'up' to 'down' spin electrons. Using
conventional amorphous alumina tunnel barriers tunneling spin polarization
(TSP) values of up to $\sim $55{\%} are found for conventional 3d
ferromagnets, such as CoFe, but using highly textured crystalline MgO tunnel
barriers TSP values of more than 90{\%} can be achieved for otherwise the
same ferromagnet [2]. Such TSP values rival those previously observed only
with half-metallic ferromagnets. Corresponding giant values of tunneling
magnetoresistance (TMR) are found, exceeding 350{\%} at room temperature and
nearly 600{\%} at 3K. Perhaps surprisingly the MgO tunnel barrier can be
quite rough: its thickness depends on the local crystalline texture of the
barrier, which itself is influenced by structural defects in the underlayer.
We show that the magnitude and the sign of the TMR is strongly influenced by
defects in the tunnel barrier and by the detailed structure of the
barrier/ferromagnet interfaces. The observation of Kondo-assisted tunneling
phenomena will be discussed as well as the detailed dependence of TMR on
chemical bonding at the interfaces [3].
[1] .S.S.P. Parkin, X. Jiang, C. Kaiser, et al., Proc. IEEE 91, 661 (2003).
[2] S. S. P. Parkin, C. Kaiser, A. Panchula, et al., Nature Mater. 3, 862
(2004).
[3] C. Kaiser, S. van Dijken, S.-H. Yang, H. Yang and S.S.P. Parkin, Phys.
Rev. Lett. 94, 247203 (2005).
To cite this abstract, use the following reference: http://meetings.aps.org/link/BAPS.2006.MAR.Y4.1