Post on 15-Jan-2016
description
Spintronics in metals and semiconductors
Tomas Jungwirth
University of Nottingham Bryan Gallagher, Tom Foxon,
Richard Campion, Kevin Edmonds, Andrew Rushforth, Chris King et al.
Hitachi Cambridge Jorg Wunderlich, Andrew Irvine, David Williams,
Elisa de Ranieri, Byonguk Park, Sam Owen, et al.
Institute of Physics ASCR Alexander Shick, Karel Výborný, Jan Zemen, Jan Masek, Vít Novák, Kamil Olejník, et al.
University of Texas Allan MaDonald, et al.
Texas A&MJairo Sinova, et al.
OutlineOutline
11.. Tunneling anisotropic magnetoresistance in transition metals Tunneling anisotropic magnetoresistance in transition metals
2. Ferromagnetism in (Ga,Mn)As and related semiconductors2. Ferromagnetism in (Ga,Mn)As and related semiconductors
3. Spintronic transistors3. Spintronic transistors
Spintronics: Spin-orbit & exchange interactions
nucleus rest frame electron rest frame
vI Q rE3
04 r
Q
3
0
4 r
rIB
EvEvB 200
1
c
EvSS 22
B2 mc
egH B
SO
Thomas precession
Coulomb repulsion & Pauli exclusion principle exchange interaction
ferromagnetism
spin-orbit interaction
DOS
AMRAMR~ 1% MR effect~ 1% MR effect
TMRTMR~ 100% MR effect~ 100% MR effect
TAMRTAMR
) vs.( ~ IMvg
)(BM
M
Exchange int.:
Spin-orbit int.:
magnetic anisotropy
Exchange int.:
)()( TDOSTDOSAFM-FM exchange bias
)(MTDOS
Au
ab intio theory Shick, et al, PRB '06, Park, et al, PRL '08
experiment Park, et al, PRL '08
TAMR in CoPt structures
spontaneous momentmag
netic su
sceptib
ility
Consider uncommon TM combinationsMn/W ~100% TAMR
Consider both Mn-TM FMs & AFMs
exchange-spring rotation of the AFMScholl et al. PRL ‘04
Proposal for AFM-TAMR: first microelectronic device with active AFM component
spin
-orb
it cou
plin
g
TAMR in TM structures
Shick, et al,unpublished
Shick, et al,unpublished
OutlineOutline
11.. Tunneling anisotropic magnetoresistance in transition metals Tunneling anisotropic magnetoresistance in transition metals
2. Ferromagnetism in (Ga,Mn)As and related semiconductors2. Ferromagnetism in (Ga,Mn)As and related semiconductors
3. Spintronic transistors3. Spintronic transistors
Magnetic materials
Ferroelectrics/piezoelectrics Semiconductors
spintronic magneto-sensors, memories
electro-mechanical transducors, large & persistent el. fields
transistors, logic,sensitive to doping and electrical gating
TM-based semiconducting multiferroic spintronicssensors & memories transistors & logic
Ferromagnetic semiconductors
GaAs - GaAs - standard III-V semiconductorstandard III-V semiconductor
Group-II Group-II Mn - Mn - dilute dilute magneticmagnetic moments moments & holes& holes
(Ga,Mn)As - fe(Ga,Mn)As - ferrromagneticromagnetic semiconductorsemiconductor
Need true FSs not FM inclusions in SCs
Mn
Ga
AsMn
Mn-d-like localmoments
As-p-like holes
Mn
Ga
AsMn
EF
DO
S
Energy
spin
spin
GaAs:Mn – extrinsic p-type semiconductor
FM due to p-d hybridization
(Zener local-itinerant kinetic-exchange)
valence band As-p-like holes
As-p-like holes localized on Mn acceptors
<< 1% Mn ~1% Mn >2% Mn
onset of ferromagnetism near MIT
(Ga,Mn)As synthesis
Low-T MBE to avoid precipitation
High enough T to maintain 2D growth
need to optimize T & stoichiometry for each Mn-doping
Inevitable formation of interstitial Mn-donorscompensating holes and moments need to anneal out
high-T growth
optimal-T growth
Interstitial Mn out-diffusion limited by surface-oxide
GaMnAs
GaMnAs-oxide
Polyscrystalline20% shorter bonds
MnI++
O
Optimizing annealing time & temperature (removing int. Mn & keeping MnGa in place) is essential Rushforth et al, unpublished
x-ray photoemission
Olejnik et al, ‘08
10x shorther annealing with etch
0 1 2 3 4 5 6 7 8 9 100
20
40
60
80
100
120
140
160
180
TC(K
)
Mntotal
(%)
Indiana & California (‘03): “ .. Ohno’s ‘98 Tc=110 K is the fundamental upper limit ..” Yu et al. ‘03
California (‘08): “…Tc =150-165 K independent of xMn>10% contradicting Zener kinetic exchange ...”
Nottingham & Prague (’08): Tc up to 188 Kso far
“Combinatorial” approach to growthwith fixed growth and annealing cond.
?Mack et al. ‘08
Tc limit in (Ga,Mn)As remains open
Weak hybrid.Delocalized holeslong-range coupl.
Strong hybrid.Impurity-band holesshort-range coupl.
InSb
GaP
d5
(Al,Ga,In)(As,P) good candidates, GaAs seems close to the optimal III-V host
Other (III,Mn)V’s DMSs
Mean-field butlow Tc
MF
Large TcMF but
low stiffness
Kudrnovsky et al. PRB 07
III = I + II Ga = Li + Zn
Other DMS candidates
Masek et al. PRL 07But Mn isovalent in Li(Zn,Mn)As
no Mn concentration limit and self-compensation
possibly both p-type and n-type ferromagnetic SC
(Li / Zn stoichiometry)
GaAs and LiZnAs are twin SC
(Ga,Mn)As and Li(Zn,Mn)As
should be twin ferromagnetic SC
Towards spintronics in (Ga,Mn)As: FM & transport
Dense-moment MSF<< d-
Eu - chalcogenides
Dilute-moment MSF~ d-
Critical contribution to resistivity at Tc
~ magnetic susceptibility
Broad peak near Tc disappeares with annealing (higher uniformity)???
Ni
(Ga,Mn)As (Prague Nottingham)
Fe
Critical contribution at Tc to d/dT like TM FMs
d/dT ~ cv
F ~ d-
Fisher & Langer ’68Novak et al., ‘08
)/1~~( dkk F
2)(~ Suncor
~)0~~( Fkk
smalluncor
vcdTddTd ~/~/
Tc
Tc
EuCdSe Ni
MF
][~),(~)( 002 SSSSJTRT iipdi
0k1kd
1~kd
As-p-like holes
Ferromagnetism & strong spin-orbit coupling
LSdr
rdV
err
mc
p
mc
SeBH effSO
)(1
Strong SO due to the As p-shell (L=1) character of the top of the valence band
V
BBeffeff
pss
Beff Bex + Beff TAMR discovered in (Ga,Mn)As Gold et al. PRL’04
Mn
Ga
AsMn
SO couped carries scattering coherently off Coulomb & polarized-magnetic potential of Mn
>
magnetic. only
max AMR
>
MnGa
~
AMR in DMSs
sign and magnitude (numerical) consistent with experiment
Remark: Extraordinary MRs & quantum coherent transport phenomena
dirty metal UCF
OutlineOutline
11.. Tunneling anisotropic magnetoresistance in transition metals Tunneling anisotropic magnetoresistance in transition metals
2. Ferromagnetism in (Ga,Mn)As and related semiconductors2. Ferromagnetism in (Ga,Mn)As and related semiconductors
3. Spintronic transistors3. Spintronic transistors
0.0 0.5 1.0 1.5 2.0 2.5 3.0 3.5 4.0
0
2
4
6
8
10
0V 3V 5V 10V
carr
ier
dens
ity
[ 10
19 c
m-3
]
GaMnAs layer thickness [nm]
Gating of the highly doped (Ga,Mn)As: p-n junction FET
p-n junction depletion estimates
Olejnik et al., ‘08
~25% depletion feasible at low voltages
20 22 24 26 28 30 32 34
18.6
18.8
19.0
19.2
19.4
[10
-3c
m]
T [K]
Vg = 0V
22.5
23.0
23.5
24.0
24.5 Vg = 3V
20 22 24 26 28 30 32 34
-200
-100
0
100
d/d
T [1
0-6
T [K]
-300
-200
-100
0
AM
RIncreasing and decreasing AMR, Tc, coercivity with depletion
-400 -200 0 200 400
0.96
0.98
1.00
1.02 Vg [V] -1.0 0.0 1.0 2.0 2.5 3.0 3.5
R(
B)/R
(B=0
)
B [Oe]-1 0 1 2 3 4
150
200
250
300
coer
cive f
ield [
Oe]
Vg[V]
30 40 50 60 70 80 90 100
100
200
65K62K
dR/d
T
T (K)
depletion accumulation
Persistent variations of magnetic properties with ferroelectric gates
Stolichnov et al., Nat. Mat.‘08
exy = 0.1%
exy = 0%
Electro-mechanical gating with piezo-stressors
Rushforth et al., ‘08
Strain & SO
Electrically controlled magnetic anisotropies
Single-electron transistor
Two "gates": electric and magnetic
(Ga,Mn)As spintronic single-electron transistor
Huge, gatable, and hysteretic MR
Wunderlich et al. PRL ‘06
AMR nature of the effect
normal AMR Coulomb blockade AMR
GMMGG0
20
C
C
e
)M(V&)]M(VV[CQ&
C2
)QQ(U
electric && magneticmagnetic
control of Coulomb blockade oscillations
n-1 n n+1 n+2n-1 n n+1 n+2
EC
QQindind = = nnee
QQindind = (= (n+1/2)n+1/2)eeQ0
Q0
e2/2C
Q
0
'D
'
e
)M(Q)Q(VdQU
[010]
M[110]
[100]
[110][010]
SO-coupling (M)
Source Drain
GateVG
VDQ
Single-electron charging energy controlled by Vg and M
• CBAMR if change of |CBAMR if change of |((MM)| ~ )| ~ ee22//22CC
• In our (Ga,Mn)As ~ meV (~ 10 Kelvin)In our (Ga,Mn)As ~ meV (~ 10 Kelvin)
• In room-T ferromagnet change of |In room-T ferromagnet change of |((MM)|~100K )|~100K
• Room-T conventional SET (e2/2C >300K) possible
Theory confirms chemical potential anisotropies in (Ga,Mn)As& predicts CBAMR in SO-coupled room-Tc metal FMs
Variant p- or n-type FET-like transistor in one single nano-sized CBAMR device
0
ONONOFFOFF
1
0
ONON OFFOFF
1
VDD
VA VB
VA
VB
Vout
0
0
0
OFFOFFONON
ONON
OFFOFF
0
0
1
1
ONONOFFOFF
A B Vout0 0 01 0 10 1 11 1 1
0
01
ONON
OFFOFF
0
0
OFFOFF
1
ONON
1
1
1
1
OFFOFF
ONON
1
1
ONON
OFFOFF
1
“OR”
Nonvolatile programmable logic
VDD
VA VB
VA
VB
Vout
Variant p- or n-type FET-like transistor in one single nano-sized CBAMR device
0
ONONOFFOFF
1
0
ONON OFFOFF
1
A B Vout0 0 01 0 10 1 11 1 1
“OR”
Nonvolatile programmable logicNonvolatile programmable logic
Physics of SO & exchange
SET
Resistor
Tunneling device
Chemical potential CBAMR
Tunneling DOS TAMR
Group velocity & lifetime AMR
Device design Materials
TM FMs
(III,Mn)V, I(II,Mn)VDMSs
Mn-based TM FMs&AFMs
TM FMs,MnAs, MnSb