Bernd Lorenz - ICMR2) Helical magnetic order, exchange striction, and double exchange as the source...
Transcript of Bernd Lorenz - ICMR2) Helical magnetic order, exchange striction, and double exchange as the source...
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Tuning multiferroics under extreme conditions: Effects of high pressure, magnetic fields, and
substitutions
Bernd LorenzTexas Center for Superconductivity and Department of Physics,
University of Houston
TCSUH
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Outline
1) Short introduction: Multiferroics (MF)
2) Helical magnetic order, exchange striction, and double exchange as the source of ferroelectricity
3) The significance of magnetoelastic effects and spin-lattice interaction – how to detect them in MF
4) The effects of high pressure on the MF phases and ferroelectricity
5) Tuning MF properties by ionic substitutions
6) Summary
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1. Short introduction: Multiferroics
Multiferroic :Materials showing magnetic (FM, AFM) and ferroelectric (FE) orders coexisting in some temperature range and a sizable coupling between them.
Eerenstein, Nature 2006
Materials are rare since two fundamental symmetries have to be broken:
Time reversal symmetry (magnetic order) andSpatial inversion symmetry (ferroelectric order)
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?
Important role of frustration:Note:
If Humans get frustrated ..... they often don’t know what to do .....and a small perturbation can change their mood
The same “rules” apply to frustrated physical systems
Examples of frustrated orders:
1. Geometric frustration
AFM spins on a triangular lattice are frustrated =>
Noncollinear order, spin rotations, complex phase diagrams (HoMnO3)
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2. Frustration due to competing interactions
AFM
E-type
J1>0 J2>0
Ground state energy (Ising limit):AF: N (J2-J1)
E-type: - N J2
Transition from AF to E-type at J1 = 2 J2
Same arguments hold for J1 < 0 (FM to E-type)
The devil’s tree of the Isingmodel
In a simple Ising (Heisenberg) model of spins with AFM/FM first and AFM second neighbor interaction there is frustration and degeneracy near J1=2J2
This results in a complex phase diagram at T>0 with many commensurate and incommensurate phases
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Competing interactions in RMnO3
Superexchange couplings Mn3+ - O - Mn3+ :
J1<0 (FM) but J2>0 (AFM)
depend on bond angle Φ (Mn-O-Mn), which is controlled by size of R
Frustration and “exotic” phases near Φ ≈ 145 deg
Magnetic phase diagram of orthorhombic RMnO3
a
b
O
R
Mn
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Novel physical effects in multiferroic compounds:
Ferroelectricity induced by magnetic orders ( e.g. TbMnO3, Ni3V2O8, MnWO4 )
Rotation of FE polarization by 90˚ in magnetic fields ( TbMnO3, MnWO4 )
Complete reversal of FE polarization by magnetic fields ( TbMn2O5 )
Giant magneto-dielectric effect in DyMn2O5
(increase of dielectric constant by more than 100 % in magnetic fields)
Ferromagnetic order induced by electric fields ( HoMnO3 )
Complex magnetic phase diagrams with incommensurate and commensuratemagnetic structures, lock-in transitions, and multicritical points
Experimental discovery of a new excitation - electromagnons
. . . . .
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Experimental discovery of a new fundamental excitation – The electromagnon
Theoretically predicted in 1970: Hybrid excitation of a phonon and a magnondue to strong spin-phonon coupling
Low-energy excitation (10 ... 20 cm-1) predicted in optical experiments (electric field can excite a magnon)
Experimentally confirmed in 2006 in different multi-ferroic compounds:
magnon phonon
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2. Helical magnetic order, exchange striction, anddouble exchange as possible sources of FE
Search for common features (magnetic orders) in different MF compounds: The important role of neutron scattering experiments as the key investigation
TbMnO3
HT IC order
sinusoidal modulation
LT IC order
helical (spiral) modulation (spatial inversion symmetry is broken)
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Ni3V2O8
Only LTI phase is ferroelectric !
HT IC order sinusoidal modulation, inversion symmetry
LT IC order helical (spiral) modulation, no IS
Commensurate order sinusoidal modulation, inversion symmetry
Magnetic frustration is due to the geometry (kagome) with AFM exchange
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WMnO4
Same phase sequence:
PM → Coll. ICM AF3
→ Helical ICM AF2 (ferroelectric)
→ Coll. CM AF1 ( ↑↑↓↓ )
Very different compounds and structures reveal similar phenomena:
Ferroelectricity arising in a spiral magnetic phase The microscopic origin of FE is the symmetry of the magnetic order (breaking the spatial inversion)
Frustration due to competing intra-chain interactions (FM / AFM)
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FE polarization induced by non-collinear helical spins
Katsura et al., PRL 2005
Spin-orbit coupling partially lifts the degeneracy of the Mn3+ d-orbitals (t2g)
Hopping Mn ↔ O is treated perturbatively in second order
Polarization of electronic orbitals :
( )2112~ eeeP rrrr××
Sergienko/Dagotto, PRB 2006
Considered oxygen displacement at FE transition due to Dzyaloshinskii-Moriya interaction
DM interaction does stabilize the helical spin structure and the oxygen displacements resulting in the FE polarization
spin current
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Symmetry and Landau theory (Kenzelmann, Mostovoy)
Lowest order coupling Φem(P,M) between FE polarization, P, and magnetic modulation, M, that is invariant upon time reversal and spatial inversion:
t -> -t : P -> P and M -> -M Φem quadratic in M
x -> -x: P -> -P and M -> M Φem ~ P and ∇M (Lifshits invariant), P uniform
for cubic symmetry: Φem = const P* [ M(∇*M) – (M*∇)M ]
Φe = P2/(2χe) =>
P = const χe [ M(∇*M) – (M* ∇)M ]
Spiral magnetic order: M = m1 e1 cos(Qx) + m2 e2 sin(Qx) + m3e3
Average polarization: <P> = const χe m1 m2 [ e3 × Q ]
Sinusoidal magnetic order: m1 or m2 =0 => <P> = 0
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FE polarization induced by exchange striction of frustrated spins
Cheong/Mostovoy, Nature Mat. 2007
Two frustrated spins tend to separate to reduce magnetic exchange energy
Applies to: E-type (↑↑↓↓) magnetic order due to competing NN and NNN interactions
If the associated ions have different charges =>local polarization of the lattice
Can add up to macroscopic polarization and ferroelectricity
No need of non-collinear spin order
Examples:
Ising chain magnet Ca3CoMnO6 (Choi et al., PRL 2008)
RMn2O5 (R = rare earth, Y, Bi)
but not RMnO3 with E-type magnetic order (HoMnO3) - no charge order
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Ferroelectricity due to possible exchange striction effects in RMn2O5
a
b
c
P
Mn4+
Mn3+
Magnetic structure from neutron scattering
Superexchange interactions determine exchange parameters between Mn spins
At least 5 different exchange integrals can be distinguished ⇒ Mostly AFM
Ionic displacements relax the magnetic frustration and generate the polarization along the b axis
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Ferroelectricity in Multiferroics with E-Type Magnetic Order (Theory – Double exchange model)
E-type magnetic order in RMnO3 : R = HoSergienko/Dagotto, PRL 2006:
“Double-exchange” (virtual) mechanism works against Jahn-Teller distortion in FM spin chains along a-axis
Does not involve DM interaction
Large FE polarization predicted
a
b
P
Pbnm
Problems:
Experimental – only polycrystalline samples can be synthesized (high-pressure synthesis)
Theoretical – predicted polarization is three orders of magnitude larger than measured
Dual nature of FE (electronic + ionic) recently suggested (Picozzi et al., PRL 2007)
ΔE ~ - t2/δ cosΦMn-O-Mn
0 10 20 300
5
10
15
P (μ
C/m
2 )
T (K)
H=0 5 kOe 15 kOe 20 kOe 25 kOe 35 kOe
TL
TNC
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2. Magnetoelastic effects and spin-lattice coupling – how to measure these effects ?
In multiferroics the spin-lattice interaction plays a decisive role in mediating the (improper) ferroelectricity induced by magnetic orders
The measurements of the ionic displacements and/or the macroscopic lattice strain is therefore of interest
Scattering experiments (x-ray, neutron) provide the tool to measure displacements on a microscopic level – but often lack the resolution to detect the tiny changes.
Note: The atomic displacements explaining the experimental values of the FE polarization are as small as 10-4 Å .
Only a few attempts to derive structural distortions at the magnetic and ferroelectric transitions in multiferroics have been successful.
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Capacitance dilatometer for high-resolution measurements of lattice strain
(i) Capacitance can be measured with extreme accuracy (~ 10-8)
(ii) Measuring the absolute length change of a macroscopic sample can further increase the relative resolution in proper geometry of the device
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AFM ordering at AFM ordering at TTNN=7=76 K6 KMnMn3+3+ Magnetic momentsMagnetic momentslonglong--range orderingrange orderingin the in the abab--plane plane (P6(P6’’33cc’’m)m)
Ferroelectric at Ferroelectric at 870 K870 KPolarization Polarization alongalong cc--axisaxis Z = 0
Z = C/2
b
a
Mn3+ moments rotate into the P63cm structure at 5 K
Mn3+ moments undergo a spin rotation at TSR=33 K into the P6’3cm’symmetry
Structural distortions in multiferroic (hex.) HoMnO3
Growth of high-quality single crystals from high-T solution (right) of through a floating zone furnace.
Compound is multiferroic with TC > TN
Magnetic order on triangular lattice is highly frustrated
?
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Dielectric Anomalies at the Magnetic Transitions of HoMnO3
P6’3c’mP6’3cm’
P63cm
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Dielectric Anomaly at and below TN(common to all hexagonal RMnO3)
No direct coupling between c-axis polarization and in-plane magnet-ization allowed by symmetry
Magneto-dielectric coupling via lattice deformation (magneto-elastic effect)
Search for structural anomalies or lattice strain
Strong spin-lattice interactions required
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Thermal Expansion Anomalies in HoMnO3 (and YMnO3)
0 50 100 150 200 2500.997
0.998
0.999
1.000
TN
H o M n O3
c-axis
a-axis
L(T)
/L(2
93 K
)
T (K)
Strong anomalies at TN :a (b) -axis shrinks c-axis expandsNegative c-expansivity for all T<300 K
λ-type anomaly of α consistent with heat capacity ⇒ 2nd order transition
60 70 80 90 100
30
40
50
HoMnO3
Cp
(J/m
ol K
)
At TSR sharp peaks of αa and αc show that the spin rotation transition is associated with a volume increase below TSR, ΔV/V = 6*10-7
T (K)
Similar expansion anomalies are also found in YMnO3 at TN
The negative c-axis expansivity appears to be a common feature of hexagonal RMnO3
50 100 150 200 250
-10
-5
0
5
10
15
20
HoMnO3
TN
TSR
c-axis
a-axis
α (
106 K
-1)
32 36
-1
0
1
2
a-axis
c-axis
Δα (
106 K
-1)50 100 150 200 250
-10
0
10
20
TN
Y M n O3
c-axis
a-axis
T (K)
Recently confirmed by HR neutron scattering (Lee et al., PRB 71, 180413(R) , 2005)
Evidence for increase of FE polarization below TN
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Strong spin-spin and spin-lattice coupling in RMnO3
In-plane Mn-Mn superexchange interactions are very strong
AFM long range order is suppressed due to frustration and weak inter-plane exchange
Sizable spin-spin correlations well above TN growing stronger for decreasing T→TN(evidence from magnetization and neutron scattering, Lonkai et al. J. Appl. Phys. 93, 8191, 2003)
Magnetostriction (spin-lattice coupling) leads to a shortening of in-plane distances with decreasing T and, via lattice elasticity, to the increase of the c-axis length
These effects are dramatically enhanced at TN (peaks of αa and αc with opposite signs)
Through the spin-lattice interaction the spin fluctuations couple with the FE displacement coordinate
C. Zhong and J. Fang Solid State Comm. 128, pp449 (2003)
Model description:Model description:
meem HHHH ++=( )( ) ( )( ) ∑∑∑ −++−++= ⊥⊥
i
zi
li
yl
yi
xl
xi
zl
zi
ji
yj
yi
xj
xi
zj
zi
m shssssJssJssssJssJ,
//
,
// 22 αH
∑∑∑ −−⎟⎟⎠
⎞⎜⎜⎝
⎛+−=
ii
jiji
iii
ie EuuUuubuam
P,
422
422H
( )( )∑ ++=jik
yj
yi
xj
xi
zj
zik
me ssssgssgu,,
212H
Magnetic subsystem
Ferroelectricity
Spin-lattice coupling
ε ∼ 1/<uk>2 scales with 1/c2
0 50 100
15.4
15.6
15.8
16.0
16.2
TN
εT (K)
0 50 100
0.9995
1.0000
1.0005
[c(T
)/c(2
93 K
)] -2
T (K)
15.4
15.6
15.8
16.0
16.2
T2
TSR
TN
ε
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Many magnetic structures are nearly degenerated at low temperatures Magnetic and FE orders are highly susceptible to external perturbations
Complex phase diagram, typical for all RMn2O5
O2-
1
2
3
4
5Space group Pbam:
MnO6 octahedra form ribbons || c and are linked by MnO5 bi-pyramids
Mainly AFM superexchange coupling between Mn moments
Ferroelectricity arises just below the AFM ordering temperature, TN ≈ 40 K
Additional phase transitions at lower T
Magnetic frustration among the Mn spins !
?
Mn4+O6
R3+
Mn3+
10 20 30 40 50
14
16
18
20
22
24
26
εT (K)
HoMn2O5
0
50
100
150
P
︵μC/m
2
︶
Structural distortions and ferroelectricity in RMn2O5
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Pressure can be used to control the magnetic/ferroelectric phases by tuning the exchange coupling constants
Essential difference between the effects of magnetic fields and pressure:
Magnetic fields couple to the complex magnetic orders of Mn- and R-moments
Pressure changes the interatomic distances and bond angles and modifies the magnetic exchange parameters
Search for structural anomalies at the FE and AFM transitions
The lattice strain associated with the ferroelectric transitions in RMn2O5 was clearly revealed
HoMn2O5 TbMn2O5
Largest lattice anomalies at the low-temperature FE transitions – this is the phase that is most susceptible to perturbations
(magnetic field, pressure)
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Other multiferroic compounds
Ni3V2O8 MnWO4
As with the RMn2O5 compounds – the strongest lattice anomalies are at the low-T transition from the ferroelectric to the reentrant paraelectric phase
→ Effects of lattice strain and external pressure are significant at low T’s
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The effect of pressure on the magnetic order is fundamentally different from the external magnetic field effects
Magnetic field couples to the moments (spins) and tends to align them
Pressure changes the interatomic distances and bond angles resulting in a control of the exchange coupling constants
For example: 3d – 2p – 3d superexchange coupling strongly depends on the Mn – O – Mn bond angle
Psuperexchange coupling J
J
The real effects of compression are more complex because of lattice anisotropies and multiple exchange constants affected by pressure
3. The effects of high pressure on the magnetic and ferroelectric phases in multiferroics
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How to measure dielectric properties and ferroelectric polarization under high-pressure conditions :
High-pressure Clamp Cell (p < 20 kbar)
Pressure Cell (parts)
Low-temperature probe
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Be-Cu cap with wires, sample, and pressure gauge Sample, lead gauge, thermocouple
Pressure is changed at RT before each cooling run
P, T measured inside (Pb manometer, thermocouple)
T-range: 1.2 K < T < 300 K
p up to 20 kbar (2 GPa)
Coaxial wires as close as possible to the sample contacts for dielectric measurements
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How to measure ferroelectric polarization via the pyroelectriccurrent method :
0 10 20 30 40 500
1
2
3
4
P (
arb.
uni
ts)
T (K)
HoMn2O5 , p=0
CM / FE1ICM / FE2
Current across a parallel-plate capacitor
V = constant R large or V = 0
Poling of FE domains needed upon cooling in electric field, measurements of spontaneous polarization upon heating in zero field
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Pressure – temperature phase diagram of N3V2O8 and WMnO4
Ni3V2O8 WMnO4
The commensurate (paraelectric) phase is stabilized under pressure and the IC helical (ferroelectric) phase is suppressed
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Why does compression favor the low-T commensurate phase in Ni3V2O8 and WMnO4 ?
(i) Thermodynamic argument
The low-T CM phase has the smaller volume (from expansion data)
(ii) Microscopic exchange and anisotropy constants
The phase sequence SIN – HEL – CM observed in both compounds has its origin in the competition of exchange interactions and anisotropy
Simple phase diagram, Ni3V2O8 (Kenzelmann et al., PRB 2006)
Pressure-induced change of the ratio K/J1 (?)
2
4
6
8
10
12
0.0 0.5 1.0 1.5 2.0
Pressure (GPa)
T (K
)
Pressure-Temperature Phase Diagram ( )2211 ∑∑∑ −+= ++i
zi
iii
iii SKSSJSSJ 2H
rrrr
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Pressure effects on magnetic structure and ferroelectricity of RMn2O5
10 20 30 40 50
14
16
18
20
22
24
26
ε
T (K)
HoMn2O5
0
50
100
150
P
︵μC/m
2
︶
Focus on the low-T transition CM → ICM at TC2 and the pressure effect on the ICM-phase
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Giant pressure effect on the low-T ferroelectric polarization of TbMn2O5
10 20 30 400
20
40
60
80
100
120 15.7 kbar
0 kbar
Pb (μ
C/m
2 )
T (K)
CM - FE1ICM - FE2
C. R. dela Cruz et al., PRB 2007
TbMn2O5
Giant pressure effect on P ( > 1300 % @ 15 K )
LT-ICM phase is suppressed at 9 kbar
Pressure effect on P P – T phase diagram of TbMn2O5
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0 10 20 30 40 500
50
100
150
200
250
Pb (μ
C/m
2 )
T (K)
pres
sure
0 kbar
8 kbar
CM-FE1ICM-FE2
Control of magnetic order (commensurability) by pressure: HoMn2O5
HoMn2O5
Pressure-induced transition ICM / FE2 → CM / FE1 phase p – T phase diagram of HoMn2O5
C. R. dela Cruz et al., PRB 2007 C. R. dela Cruz et al., Physica B 2008
Pressure changes commensurability at low T Neutron scattering under pressure !
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Recently confirmed and extended in the work of Noda’s group :Kimura et al., J. Phys. Soc. Jpn. (2008)
These data reveal phase coexistence of CM and ICM orders.
The higher critical pressures may be sample dependent.
0.0 0.2 0.4 0.6 0.8 1.00
5
10
100
150
200
250
HoMn2O
5
Δε
pressure (GPa)
P(5
K) (
mC
/m2 )
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Complex p – T phase diagram of DyMn2O5
DyMn2O5
Five phase transitions are visible in distinct changes of εand PbHigher phase complexity, pressure-induced new phase (X – phase) The “X” phase is found to be paraelectric at high pressure (mixed phase ?)Magnetic properties still need to be investigated
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Pressure-induced polarization reversal in YMn2O5
YMn2O5 is unique in the RMn2O5 family of compounds –it shows a spontaneous sign change of P at Tc2 (Inomata et al., 1996)
Problem with pyroelectric current measurements:
Poling of FE domains upon cooling is necessary to reveal the intrinsic polarization –measurements are done at E = 0 upon warming
0 20 40
P (a
rb. u
nits
)
T (K)
poling, E > 0
measure, E = 0
Additional phase transitions may destroy the FE domain alignment !
This can give rise to spurious effects or incorrect results
Poling to 5 K, ± 200 V
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In multiferroics with a paraelectric low-T phase pyroelectric current measurements can be conducted with a poling field applied, e.g. WMnO4
However, this is not possible if P reverses sign
How to maintain the FE domain alignment for current measurements if the intrinsicpolarization changes sign ?
4 8 12 16
P (a
rb. u
nits
)
T (K)
WMnO4
Experimental protocol to measure P(T) in YMn2O5 in both FE phases
(i) Poling in E > 0 to max of P (TC2, FE1)E > 0
FE1FE2
(ii) Measure in E = 0 upon warming→ Polarization of the FE1 phase
E=0
(iii) Repeat step (i)
(iv) Measure in E = 0 upon cooling→ Polarization of the FE2 phase
E = 0
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Pressure effects in YMn2O5
0 10 20 30 40 50
0.0
0.5
1.0
1.5
P (m
C/m
2 )
T (K)
16.8
13.2
11.2
10.4
9.57.50
p/kbar
0 5 10 15-0.5
0.0
0.5
1.0
1.5
20
25
30
35
40
45
P (5
K) (
mC
/m2 )
pressure (kbar)
ε b (5 K
)
R. P. Chaudhury et al., PRB 2008
The FE polarization of the low-T ICM phase is completely reversed by pressure near pC1 ~ 10 kbar.
Above pC2 ~ 14 kbar the low-T ICM is transformed into the CM phase
The FE polarization reaches its maximum in the p-induced CM phase at the lowest temperature.
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Frustration and exchange striction as the origin of ferroelectricity
a
b
c
Superexchange interactions determine exchange parameters between Mn spins
At least 5 different exchange integrals can be distinguished ⇒ Mostly AFM
Magnetic structure from neutron scattering
P
Ionic displacements relax the magnetic frustration and generate the polarization along the b axis
Mn4+
Mn3+
Understanding the pressure effects in RMn2O5
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AFM / FE domains in the CM phase of RMn2O5
Mn4+ and Mn3+ form AFM zigzag chains along the a-axis.
The spins of adjacent chains are frustrated in every second pair.
The macroscopic polarization adds up along the b-axis
The opposite FE domain results from the reversal of spins of every second chain (or phase shift by one lattice constant).
Domain 1: P > 0 Domain 2: P < 0
The magnitude and sign of P depend on the relative phase of the magnetic modulation between two adjacent chains
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Chapon et al. (PRL 2006) explained the sign change of P at TC2 with a change of phase angle φbetween the magnetic orders of adjacent chains
Magnetic structure changes at TC2 :
(i) The relative angle between spin vectors ofneighboring chains increases from ~ 0 to 40°reducing the magnetic coupling between them
(ii) The phase of the magnetic modulation between adjacent chains increases, reducingand eventually reversing the polarization
(iii) The CM magnetic order unlocks and becomes incommensurate again
The observed pressure effects can now be understood as:Decreasing the phase difference of magnetic modulation of adjacent chains → reversal of FE polarization at 10 kbar
Transition from the ICM to the CM phase at higher pressure
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5. Tuning MF properties by ionic substitutions
Replacement of magnetic ions by other (magnetic or non-magnetic) ions can have a large effect on the physics of frustrated (multiferroic) systems through
(i) Introducing magnetic moments of different size
(ii) Change of exchange coupling constants between different ions
(iii) Change of crystalline anisotropy
(iv) Introducing disorder among the magnetic ions
Since MF systems are very fragile (remember: many magnetic states/orders are close in energy) small amounts of substitutions usually result in big effects !
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Example 1: WMnO4
In MnWO4 the Mn2+ - ion can be replaced by Fe2+ :
Tuning of magnetic exchange and anisotropy in Mn1-xFexWO4 possible
Phase diagram from neutron scatteringGround state: AF1 – Phase (E-type), PE
AF3 – Phase: IC collinear (sinusoidal), PE
AF2 – Phase (x=0) : IC non-collinear (helical), FE Does ferroelectricity exist for
x > 0 ?
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Growth of a series of large single crystals with xFe = 0.25, 0.1, 0.05, 0.035, 0.02
x = 0.035x = 0.05
4 6 8 10 12 14 160
10
20
30
40
P (μ
C/m
2 )T (K)
Mn1-xFexWO4
x = 0.00 x = 0.02 x = 0.035
0.00 0.02 0.04 0.06 0.08 0.10
8
10
12
14
16
18
T (K
)
Concentration (x)
Sinusoidal / ICM / PE
CM / PE / E type
ICM / FE
Mn1-xFexWO4
Phase diagram
The ferroelectric (helical) phase is completely suppressed by Fe substitution as low as 4 %
For x > 0.04 the transition from the ICM collinear (sinusoidal) phase proceeds directly into the commensurate (E-type) phase, both phases are paraelectric.
Confirmed by neutron scattering experiments.
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Example 2: CuFeO2
T. Kimura et al., PRB 2006
S. Seki et al., PRB 2007
CuFeO2 is paraelectric at H=0 with a magnetic transition from a ICM< sinusoidal structure to the E-type ↑↑↓↓ magnetic order.
Replacing Fe by 2 % Al stabilizes the non-collinear (helical) magnetic order and ferroelectricity
Note the sensitivity of the E-type ground state !
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Acknowledgements
Many students and collaborators have contributed to the success of our work on multiferroic materials:
R. P. Chaudhury
C. R. dela Cruz
F. Yen
Y.Q. Wang
Y.Y. Sun
C. W. Chu
M. Gospodinov (Sofia, Bulgaria)
S. Park (Rutgers)
S.W. Cheong (Rutgers)
W. Ratcliff (NIST)
J. Lynn (NIST)
F. Ye (ORNL)
H. Mook (ORNL)Funding:NSFDoEState of Texas through TCSUHT.L.L. Temple FoundationJohn J. and Rebecca Moores EndowmentBulgarian Science Fund