Transcript Slide 1

Dilute moment ferromagnetic semicinductors for spintronics
Tomas Jungwirth
Bryan Gallagher, Tom
Foxon, Richard Campion,
Kevin Edmonds,
Andrew Rushforth, Devin
Giddings, Chris King, et al.
Jan Mašek, Alexander Shick
Karel Výborný, Jan Zemen,
Vít Novák, et al.
Nottingham
Prague
NANOSPIN
Cambridge
CNRS, Wuezburg,
Warsaw, Thales
Texas Universities
Jairo Sinova, Allan H.
MacDonald. et al.
Jorg Wunderlich, David
Williams, Andrew Irvine,
Kaiyou Wang, Elisa De
Ranieri, et al.
(Ga,Mn)As (and realated DMSs) & spintronics:
Ideal systems for exploring basic physics and new functionality concepts
s
Ga
As
Mn
p
py
V
Hso
Mn
px
Dilute moment ferromagnets based on
semiconductor material:
Ferromagnetic Mn-Mn coupling mediated by
GaAs host-like As p-orbital band states:
dependence on doping
strongly exchange split and SO coupled
yet relatively simple carrier bands
low saturation magnetization
Spintronics based on extraordinary magnetoresistance effects
(AHE, AMR, STT,TMR,....)
Extraordinary magnetoresistance:
response to internal magnetization in ferromagnets
often via quantum-relativistic spin-orbit coupling
majority
_
__
FSO
FSO
I
minority
V
e.g. anomalous
Hall effect
anisotropic
magnetoresistance
For decades controversial in conventional metal FMs:
model of (non-SO-coupled non-exchange-split) s-state
carriers and localized d-states  difficult to match with
microscopic bands of mixed s-d character
M
Origin of AMR
Basic symmetry arguments for zincblende DMSs (GaMnAs)
SO-coupling – spherical model
FM exchange spiitting
ky
~(k . s)2
scattering rate
kx
M
~Mx . sx
current

[110]
hot spots for scattering of states moving  M
 R(M  I)> R(M || I)
Successful microscopic modelling
still R(M  I)> R(M || I) plus
magnetocrystalline anisotropy corrections
(M vs. crystal axes)
AMRtheor.
AMRexp.
A family of new AMR effects dicovered in GaMnAs
- TAMR sensor/memory elemets
TAMR
TMR
no need for exchange biasing
or spin
Au coherent tunneling
predicted and recently confirmed to exist in conventional metal FMs
- CBAMR spintronic transistor
combining processing with
permanent storage and p-type
and n-type transistor characteristics
predicted to exists in conventional metal FMs
Spintronic transistor based on CBAMR
Huge, gatable, and hysteretic MR
Single-electron transistor
Two "gates": electric and magnetic
Spintronic transistor based on CBAMR
Source
Q VD
Drain
Gate
VG


( Q  Q0 )
( M ) C
U
& Q0  CG [ VG  VM ( M )] &VM 
2C
e
CG
2
electric
& magnetic
control of Coulomb blockade oscillations

magnitude of MR reaches magnitude of CB oscillations
M || <111>
Strong spin-orbit coupling  band structure depends on M
M || <100>
 chemical potential depends on M
• CBAMR if change of |(M)| ~ e2/2C
• In (Ga,Mn)As ~ meV (~ 10 Kelvin)
• In room-T ferromagnet change
of |(M)|~100K
CBAMR SET
• Generic effect in FMs with SO-coupling
• ~10 K in GaMnAs, ~100 K in room-Tc metal FM
• Combines electrical transistor action
with magnetic storage
• Switching between p-type and n-type transistor
by M  programmable logic
(Ga,Mn)As (and realated DMSs) & spintronics:
Ideal systems for exploring basic physics and new functionality concepts
s
Ga
As
Mn
p
py
V
Hso
Mn
px
Dilute moment ferromagnets based on
semiconductor material:
Ferromagnetic Mn-Mn coupling mediated by
GaAs host-like As p-orbital band states:
dependence on doping
strongly exchange split and SO coupled
yet relatively simple carrier bands
low saturation magnetization
unprecedented micromagnetics  Jorg Wunderlich's talk