APS March Meeting 2010
Volume 55, Number 2
Monday–Friday, March 15–19, 2010;
Portland, Oregon
Session H3: Room Temperature Semiconductor Spintronics
8:00 AM–11:00 AM,
Tuesday, March 16, 2010
Room: Oregon Ballroom 203
Sponsoring
Unit:
GMAG
Chair: Berry Jonker, Naval Research Laboratory
Abstract ID: BAPS.2010.MAR.H3.1
Abstract: H3.00001 : Multiferroic spintronics
8:00 AM–8:36 AM
Preview Abstract
Abstract
Author:
Agn\`es Barth\'el\'emy
(Unit\'e Mixte de Physique CNRS/Thales)
Multiferroics are singular materials that can exhibit simultaneously
electric and magnetic orders, with in some cases a
magnetoelectric between
the two. As such, these compounds bring new functionalities to
spintronics
[1] and new device possibilities, such as multinary memory
elements or
magnetic random access memories with electrical write operation. For
practical purposes, the main problem of multiferroics is their
scarcity.
Notable examples in the perovskite family include the low
temperature
ferromagnetic ferroelectric material (La,Bi)MnO3, and the room
temperature
antiferromagnetic ferroelectric compound BiFeO.
We will present experiments on 2 to 4 nm thick ferromagnetic
(La,Bi)MnO3
layers used as tunnel barriers in junctions with a La2/3Sr1/3MnO3
bottom
electrode and a Au top electrode. In these junctions, the tunnel
current is
modulated by the ferromagnetic order parameter of the barrier
material via
the spin-filter effect, giving rise to a TMR of up to 100{\%} [2,3].
Remarkably, 2 nm-thick (La,Bi)MnO3 films are also ferroelectric [4].
Accordingly, the concomitance of ferromagnetism and
ferroelectricity in a
unique tunnel barrier allows obtaining a four level resistance
state from
the combination of the spin-filter effect and the influence of
ferroelectricity on tunneling [4].
The interest of the antiferromagnetic-ferroelectric BiFeO3 is for
room-temperature control of magnetization by the application of
an electric
field. We will show that BiFeO3 films can be used to establish a
robust
exchange-bias effect [5]. Remarkably, the exchange field
correlates with the
multiferroic domain size, as expected from Malozemoff's model of
exchange
bias extended to multiferroics [6]. Perspectives for electric
control of
spintronics devices will be given.
A way to overcome the scarcity of multiferroic materials at room
temperature
is to design a artificial multiferroics by combining
ferroelectric and
ferromagnetic materials. We will present experiments on
heterostructures
combining ferroelectric tunnel barriers of BaTiO3 and ferromagnetic
electrodes (Fe or Co). This kind of heterostructures allows to
generate,
within a single device, not only a tunnel magnetoresistance (TMR)
phenomena
related to the relative orientation of the magnetization of the
electrodes
and a very large tunnel electroresistance (TER) -- up to
750000{\%} at 3nm-
induced by the ferroelectric polarisation of the barrier [7].
They also give
rise to a unusual modulation of the spin polarisation at the
interface by
the ferroelectricity [8] resulting in a large TEMR (Tunnel Electro
MagnetoResistance) effect.
[1] M. Bibes and A. Barth\'{e}l\'{e}my, IEEE Trans. Electron Dev.
54, 1003
(2007)
[2] M. Gajek et al, J. Appl. Phys 97, 103909 (2005)
[3] M. Gajek et al, Phys. Rev. B 72, 020406(R) (2005)
[4] M. Gajek et al, Nature Materials 6, 296 (2007)
[5] H. B\'{e}a et al, Appl. Phys. Lett. 89, 242114 (2006)
[6] H. B\'{e}a et al, Phys. Rev. Lett 100, 017204 (2008)
[7] V. Garcia et al.; Nature 460, 81 (2009)
[8] C. G. Duan et al.~; Phys. Rev. Lett. 97, 047201 (2006)
To cite this abstract, use the following reference: http://meetings.aps.org/link/BAPS.2010.MAR.H3.1