Transcript Slide 1

Ferromagnetic semiconductor materials and spintronic
transistors
Tomas Jungwirth
Institute of Physics ASCR
Alexander Shick, Karel Výborný, Jan Zemen,
Jan Masek, Vít Novák, Kamil Olejník, et al.
Hitachi Cambridge, Univ. Cambridge
Jorg Wunderlich, Andrew Irvine, David Williams,
Elisa de Ranieri, Byonguk Park, Sam Owen, et al.
University of Nottingham
Bryan Gallagher, Tom Foxon,
Richard Campion, Kevin Edmonds,
Andrew Rushforth, Chris King et al.
Texas A&M
Jairo Sinova, et al.
University of Texas
Allan MaDonald, et al.
Electric field controlled spintronics
From storage to logic
HDD, MRAM
STT MRAM
Spintronic Transistor
controlled by
Magnetic field
spin-polarized
charge current
control by
electric gates
Low-voltage controlled
magnetization and
magnetotransport
Magnetic race track memory
Outline
1) Sensitivity to electric fields via magnetic anisotropies
generic to both metals and semiconductors with spin-orbit coupling
- Tunneling AMR device
- Coulomb blockade AMR spintronic SET
2) Direct charge depletion effects on electric&magnetic proprties
ferromagnetic semiconductors are the favorable systems here
- GaMnAs and related dilute-moment ferromagnetic semiconductors
- GaMnAs-based p-n junction spintronic FET
AMR
FM exchange int.:
Spin-orbit int.:
TMR

M


 ~ vg (M vs. I )
TAMR

TDOS(M )
Au
FM exchange int.:
TDOS()  TDOS()
Discovered in GaMnAs Gould et al. PRL’04
Bias-dependent magnitude and sign of TAMR
Shick et al PRB ’06, Parkin et al PRL ‘07, Park et al PRL '08
ab intio theory
TAMR is generic to SO-coupled
systems including room-Tc FMs
Park et al PRL '08
experiment
Devices utilizing M-dependent electro-chemical potentials: FM SET
SO-coupling  (M)
Q VD
Source
Drain
Gate
VG
[110]
[010]

Q( M )
'
'
U   dQ VD ( Q ) 
e
0
Q
[100]
[110]
M
[010]


( Q  Q0 )
( M ) C
U
& Q0  CG [ VG  VM ( M )] &VM 
2C
e
CG
2
electric
& magnetic
control of Coulomb blockade oscillations
(Ga,Mn)As nano-constriction SET
CB oscillations shifted by changing M
(CBAMR)
Wunderlich et al, PRL '06
Electric-gate controlled magnitude and sign of
magnetoresistance  spintronic transistor
or
Magnetization controlled transistor characteristic
(p or n-type)  programmable logic
Outline
1) Sensitivity to electric fields via magnetic anisotropies
generic to both metals and semiconductors with spin-orbit coupling
- Tunneling AMR device
- Coulomb blockade AMR spintronic SET
2) Direct charge depletion effects on electric&magnetic proprties
ferromagnetic semiconductors are the favorable systems here
- GaMnAs and related dilute-moment ferromagnetic semiconductors
- GaMnAs-based p-n junction spintronic FET
Ferromagnetic semiconductor GaAs:Mn
DOS
spin 
Jungwirth et al, RMP '06
EF
~1% Mn
<< 1% Mn
>2% Mn
Energy
spin 
onset of ferromagnetism near MIT
As-p-like holes localized on Mn acceptors
valence band As-p-like holes
Ga
As-p-like holes
FM due to p-d hybridization
(Zener kinetic-exchange)
(Ga,Mn)As:
- heavily-doped SC 
difficult to grow and gate
- dilute moment FM 
difficult to achieve high Tc
Mn
Mn-d-like local
moments
Mn
As
(Ga,Mn)As growth
high-T growth
optimal-T growth
Low-T MBE to avoid precipitation & high enough T to maintain 2D growth
 need to optimize T & stoichiometry for each Mn-doping
Detrimental interstitial AF-coupled Mn-donors
 need to anneal out (Tc can increase by more than 100K)
Annealing also needs to be optimized for each Mn-doping
No indication for reaching technological or
physical Tc limit in (Ga,Mn)As yet
Tc up to 187 K at 12% Mn doping
Novak et al. PRL ‘08
180
160
2005
Growth & post-growth
optimized GaMnAs films
140
120
1998
TC(K)
100
80
60
40
20
0
0
1
2
3
4
5
6
Mntotal(%)
7
8
9
10
Other (III,Mn)V’s DMSs
Kudrnovsky et al. PRB 07
Weak hybrid.
Mean-field but
low TcMF
InSb
Strong hybrid.
Large TcMF but
low stiffness
GaP
GaAs seems close to the optimal III-V host
Delocalized holes
long-range coupl.
d5
Impurity-band holes
short-range coupl.
coupling strength / Fermi energy
Magnetism in systems with coupled dilute moments
and delocalized band electrons
band-electron density / local-moment density
Jungwirth et al, RMP '06
Other DMS candidates
III = I + II  Ga = Li + Zn
GaAs and LiZnAs are twin SC
(Ga,Mn)As and Li(Zn,Mn)As
should be twin ferromagnetic SC
But Mn isovalent in Li(Zn,Mn)As
Masek et al. PRL 07
 no Mn concentration limit and self-compensation
 possibly both p-type and n-type ferromagnetic SC
(Li / Zn stoichiometry)
Towards spintronics in (Ga,Mn)As: FM & transport
Ordered magnetic semiconductors
Disordered DMSs
Eu - chalcogenides
Sharp critical contribution to resistivity
at Tc ~ magnetic susceptibility
Broad peak near Tc and disappeares
with annealing (higher uniformity)???

 



2
 (T ) ~ ( Ri , T ) ~ J pd [ Si  S0    Si    S0 ]
uncor  small
Tc
uncor
2
~ S 
Eu0.95Cd0.05S
k 0
kd  1
kd ~ 1
Ni, Fe
(k ~ kF ~ 1/ d ) ~ U
d / dT ~ dU / dT  cv
(k ~ kF  1/ d ~ 0) ~ 
Tc
Sharp d/dT singularity in GaMnAs at Tc – consistent with F~d-
Novak, et al. PRL‘08
Optimized GaMnAs materials with x~412% and Tc~80-185K: well behaved FMs
Annealing sequence
M ~t
t=(Tc-T)/Tc
0.3 0.4
Strong spin-orbit coupling  favorable for spintronics
Ga
Mn
As
Mn
As-p-like holes
H SO


 
 eS   p  1 dV (r ) 
 r
    Beff  
   S  L

 mc   mc  er dr 
V
s
Beff
Strong SO due to the As p-shell (L=1) character of the top of the valence band
p
Low-voltage gating of the highly doped (Ga,Mn)As
10’s-100’s Volts in conventional MOS FETs
p-n junction FET
Ohno et al. Nature ’00, APL ‘06
p-n junction depletion simulations
2x 1019 cm-3
~25-50% depletion feasible at low voltages
Owen, et al. arXiv:0807.0906
Basic charcteristics of the device
can “deplete”
magnetization
at low Vg
can deplete
charge at low Vg
30% AMR
tuneable by
low Vg
low Vg
dependent
competition
of uniaxial
and cubic
anisotropies
Magnetization switching by 10ms low-Vg pulses
Conclusion
1) Studies in GaMnAs suggest new generic approaches to
electric field controlled spintronics via magnetic anisotropies
- TAMR
- CBAMR
2) Direct charge depletion effects on electric&magnetic properties
of GaMnAs demonstrated at low gate voltages
Ga
As
- GaMnAs junction FET
Mn
Mn