2009 APS March Meeting
Volume 54, Number 1
Monday–Friday, March 16–20, 2009;
Pittsburgh, Pennsylvania
Session Y32: Focus Session: Current-Induced Magnetic Switching
8:00 AM–10:36 AM,
Friday, March 20, 2009
Room: 336
Sponsoring
Units:
GMAG DMP FIAP
Chair: Yi Ji, University of Delaware
Abstract ID: BAPS.2009.MAR.Y32.6
Abstract: Y32.00006 : A Three Terminal Approach to Spin-Torque Written MRAM Cells
9:00 AM–9:36 AM
Preview Abstract
Abstract
Author:
Patrick Braganca
(Cornell University/Hitachi Global Storage Technologies)
Magnetic random access memory (MRAM) is a potentially superior
alternative
to silicon-based memories due to a combination of properties
including
non-volatility, fast read/write times, and low power consumption.
Future
MRAM technologies have been considered which use the spin
transfer effect as
a mechanism for bit element writing. Here, a spin polarized
current passing
through a ferromagnetic element is used to reverse its moment via an
exchange of angular momentum, as opposed to the magnetic fields
from remote
write lines used in more conventional toggle MRAM [1]. However,
the large
current densities required for spin transfer reversal create
significant
barrier wearout issues in the magnetic tunnel junctions (MTJs)
used as bit
elements. One possible solution is to develop a nanopillar
structure where a
third electrode can be made to any point within a thin-film
multilayer
stack, substantially enhancing the versatility of the device by
providing
the means of applying independent electrical biases to two
separate parts of
the device. Using experimental results and micromagnetic
simulations, I will
discuss a joint magnetic spin valve/tunnel junction structure
sharing a
common free layer nanomagnet contacted by this third electrode
[2]. A
spatially nonuniform spin-polarized current flowing into the free
layer via
the low-resistance spin valve path can reverse the magnetic
orientation of
the free layer as a consequence of the spin torque effect, by
nucleating a
reversal domain at the spin injection site that propagates across
the free
layer. The free layer magnetic state can then be read out
separately via the
higher-resistance magnetic tunnel junction. This three-terminal
structure
provides a strategy for developing high performance spin-torque
MRAM cells
which avoids the need to apply a large voltage across a MTJ
during the
writing step, thereby enhancing device reliability, while
retaining the
benefits of a high-impedance MTJ for read-out.
\\[4pt]
[1] Slaughter J.M., Dave R.W., DeHerrera M., Durlam M., Engel
B.N., Janesky
J., Rizzo N.D., Tehrani S., Fundamentals of MRAM technology,
\textit{Journal of}
\textit{Superconductivity: Incorporating Novel Magnetism }15, 19
(2002).
\\[0pt]
[2] Braganca P.M., Katine J.A., Emley N.C., Mauri D., Childress
J.R., Rice
P.M., Delenia E., Ralph D.C., Buhrman R.A., \textit{IEEE Trans.
Nanotechnol.}, In press (2008).
To cite this abstract, use the following reference: http://meetings.aps.org/link/BAPS.2009.MAR.Y32.6