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Transcript
1. Physikalisches Institut, Universität Stuttgart
Aims and contents
• What is a single molecule magnet?
• What is so interesting about single molecule magnets?
• What is the origin of the slow relaxation?
• What is Quantum Tunneling of the Magnetization?
• What is Mesoscopic Quantum Coherence?
• What is the Berry Phase and how can you observe it in single molecule magnets?
2
What is a Single
Molecule Magnet
3
What is a single molecule magnet?
• A single molecule magnet is a molecule that shows slow relaxation of the magnetization of
purely molecular origin.
• It is a molecule that can be magnetized in a magnetic field, and that will remain magnetized
even after switching off the magnetic field.
• This is a property of the molecule itself. No interaction between the molecules is necessary
for this phenomenon to occur.
• This makes single molecule magnets fundamentally different from traditional bulk magnets.
• You can dissolve a single molecule magnet in a solvent or put it in some other matrix, like
a polymer, and it will still show this property.
4
What is a single molecule magnet?
• Single molecule magnets belong to the more general class of compounds called exchange
coupled clusters.
• A small number (~4 to 30) of paramagnetic transition metal ions are linked together by
simple bridges such as O2-, OH-, OCH3-, F-, Cl-, RCOO-.
• This bridge creates a superexchange pathway giving rise to an isotropic exchange coupling
in the order of 1 to 100 cm-1.
• The organic ligands on the outside shield the exchange coupled cluster from the
environment, esp. with respect to exchange interactions.
• Often single molecule magnets are portions of a mineral lattice encapsulated by organic
ligands
5
What is a single molecule magnet?
The most famous examples are Mn12Ac, Fe8, [Mn4]2
Mn12Ac
[Mn12O12(CH3COO)16(H2O)4]
4 Mn4+ ions (S = 3/2): S = 6
8 Mn3+ ions (S = 2): S = 16
Total S = 10
Mn ions are linked by O2- bridges.
Acetate ligands are bound on the outside of the
molecule.
These acetates can be chemically replaced,
tuning properties or for linking of molecules to
surfaces.
6
What is a single molecule magnet?
•The most famous examples are Mn12ac, Fe8, [Mn4]2
Fe8
[(tacn)6Fe8(O)2(OH)12(H2O)]
8 Fe3+ ions (S = 5/2)
2 ions with spin down: S = 5
6 ions with spin up:
S = 15
Total S = 10
Fe ions are linked by O2- and OH- bridges.
tacn ligands are bound on the outside of the
molecule.
In this molecule possible synthetic variations
are the counter ions (symmetry) and the
isotopes (study of hyperfine influences).
7
What is a single molecule magnet?
•The most famous examples are Mn12ac, Fe8, [Mn4]2
[Mn4]2
[Mn4O3Cl4(CH3CH2COO)3(py)3]2
1 Mn4+ ion (S = 3/2): S = 3/2
3 Mn3+ ions (S = 2): S = 6
Total S = 9/2.
Mn ions are bridged by O2-, Cl-, and
proprionate.
Pyridine and more Cl- ligands are bound on the
outside of the molecule.
There is a weak superexchange interaction
between the two molecules of the dimer.
Wernsdorfer et al., Nature 2002
8
What is so interesting
about
Single Molecule
Magnets?
9
What is so interesting about single molecule magnets?
Materials science:
• One molecule can be seen as one bit.
• This leads to unprecedented data densities.
• Conventional materials are reaching the superparamagnetic limit.
Physics:
• These systems are in between classical and quantum magnetic systems.
• They show distinct quantum properties.
10
What is the origin of
the slow relaxation of
the magnetization?
11
What is the origin of the slow relaxation of the magnetization?
• The properties of a molecular magnet are usually described in the spin Hamiltonian
model.
• Usually the strong exchange approximation is applied, meaning that the isotropic
Heisenberg exchange interaction is much stronger than all other terms in the spin
Hamiltonian.
ˆ ˆ
ˆ
H ex = JS1 ⋅ S 2
• The dimensions of the Hilbert space, (2S+1)N, for large exchange coupled clusters are
huge.
• Exact diagonalisation is still possible for systems like Fe8, when grouping together the
states with the same total spin, and using irreducible tensor methods.
Mn12Ac:
Fe8:
[Mn4]2:
1.0 x 108
1.7 x 106
2.5 x 105
spin ground state
12
What is the origin of the slow relaxation of the magnetization?
• The large S ground state has 2S+1 spin microstates, which correspond to the MS states
in the absence of transverse anisotropy.
• These can be split up in zero field by spin-orbit coupling or magnetodipolar interactions if
S>½. This is called zero-field splitting.
• Magnetodipolar interactions are usually small (10-1 cm-1) but the only source of ZFS for
organic radicals.
• The orbital angular momentum of the electronic ground state is usually quenched by
spin-orbit coupling and/or (Jahn-Teller) distortion.
• Spin-orbit coupling can mix orbital angular momentum of the electronically excited
state into the ground state.
13
What is the origin of the slow relaxation of the magnetization?
•
The zero-field splitting can be described by a term in the spin Hamiltonian:
⎛ Dxx
⎜
D=⎜ 0
⎜ 0
⎝
0
Dyy
0
•
Here D is a 3 x 3 matrix:
•
We can rewrite the spin Hamiltonian term as:
0 ⎞
⎟
0 ⎟
Dzz ⎟⎠
ˆ
ˆ
ˆ
H
ZFS = S ⋅ D ⋅ S
ˆ 2 − S ( S + 1) / 3] + E (Sˆ 2 − Sˆ 2 )
ˆ
H
=
D
S
[
ZFS
z
x
y
•
where:
D = 3Dzz / 2
E =| Dxx − Dyy | / 2
•
The D term changes the energies of the MS states.
•
The E terms mixes the MS states (with ∆MS=2), i.e. the pure MS states are no
longer the energy eigenstates of the system.
14
What is the origin of the slow relaxation of the magnetization?
•
•
•
•
The zero-field splitting can be expanded in a series of magnetic multipoles, where
we just saw the first term.
In principle terms up to the order of 2S can be included.
For terms higher than the second power of the spin operators, usually Stevens
operator equivalents are used.
The fourth order term in the spin Hamiltonian is:
k
k
ˆ
H
ZFS = ∑ B4 O 4
k
•
•
•
•
•
•
The Stevens operators O4k are linear combinations of the spin operators to the
fourth power.
The sum runs over k = 0 to k = 4.
For tetragonal symmetry only terms with k = 0 and k = 4 are nonzero.
For trigonal symmetry only terms with k = 0 and k = 3 are nonzero.
For orthorhombic symmetry, only terms with k = 0, k = 2, and k = 4 are nonzero.
These terms correspond to higher order mixing of excited states into the ground
state.
15
What is the origin of the slow relaxation of the magnetization?
•
The full spin Hamiltonian is then:
ˆ 0 + g µ Sˆ H + E (Sˆ 2 − Sˆ 2 ) + B 2O
ˆ 2 + B 4O
ˆ 4 + g µ Sˆ H
ˆ = D[Sˆ 2 − S ( S + 1) / 3] + B 0O
H
z
B z
z
x
y
B x, y
x, y
4
4
4
4
4
4
Axial terms change the
energies of the spin
microstates but not the
characters.
Transverse terms
change the characters
of the spin microstates.
16
What is the origin of the slow relaxation of the magnetization?
One can plot the energies of the microstates against MS
....or against the angle of the magnetic moment with the quantisation axis.
0
0
–1
Energy (cm )
-10
-1
Energy (cm )
-10
-20
-30
01
2
3
4
5
-4
-5
6
-20
-6
7
-7
8
-30
-3
-2
-8
9
-9
-40
-40
-10
-5
0
MS
5
10
-10
10
∆E = DS2
<Bc
17
-1 0
What is the origin of the slow relaxation of the magnetization?
Phonon induced transitions between spin microstates are only allowed with
∆MS = 1 or ∆MS = 2.
This creates an energy barrier towards thermal inversion of the magnetic
moment.
0
10
9
0
–1
Energy (cm )
-10
01
2
3
4
5
-4
-5
6
-20
8
10
7
6
5
4
3
2
1
0
-1
-2
-3
-4
-5
-6
-7
-6
7
-7
8
-30
-3
-2
-1 0
-8
9
-9
10
-40
-10
10
∆E = DS2
-8
-9
-10
18
What is the origin of the slow relaxation of the magnetization?
10
Experimental determination of the zero field splitting:
0
-1
High Field Electron Paramagnetic Resonance (HFEPR)
10
-2
Inelastic Neutron Scattering (INS)
10
-3
Frequency Domain Magnetic Resonance (FDMRS)
10
0 01
–1
Energy (cm )
-10
2
3
4
5
-3
-4
-5
6
-20
-7
8
-8
9
10
-40
∆M = 1
-1 0
-9
-10
∆M = -1
15 K
0
10
-1
10
-2
10
-3
7.5 K
10
-6
7
-30
-2
Transmission
10
0
10
-1
10
-2
10
-3
5.0 K
6
8
10
12
-1
Frequency (cm )
Mn12Ac
19
What is Quantum
Tunneling of the
Magnetization?
20
What is Quantum Tunneling of the Magnetization (QTM)?
• In 1995 it was discovered that there are steps at regular field intervals in the magnetic
hysteresis curve of Mn12Ac.
• Apparently at certain fields, the magnetisation relaxes faster.
• This phenomenon became later known as Quantum Tunneling of the Magnetisation.
0.020
0.015
0.010
1.8 K
2.0 K
2.2 K
2.4 K
2.6 K
4.2 K
M (emu)
0.005
0.000
-0.005
-0.010
-0.015
-0.020
-30000 -20000 -10000
0
H / Oe
10000 20000 30000
21
What is Quantum Tunneling of the Magnetization (QTM)?
• In zero field, the levels on the left and right
sides of the potential energy double well
are degenerate.
0 01
2
–1
Energy (cm )
-10
• In the absence of transverse anisotropy,
the energy eigenstates of the systems are
the pure MS states.
-3
-4
-5
6
-20
-30
-1 0
-6
7
-7
8
-8
9
10
-9
-10
coefficient
-40
coefficient
3
4
5
-2
M
M
22
What is Quantum Tunneling of the Magnetization (QTM)?
0 01
2
• As soon as there is a transverse anisotropy, the
MS states are no longer the energy eigenstates.
• Near the bottom, the eigenstates are then the
superpositions of the MS states on the left and
right of the potential energy double well.
• At higher energy the second order transverse
anisotropy mixes MS levels with ∆MS=2, and the
fourth order transverse anisotropy those with
∆MS=4.
–1
Energy (cm )
-10
3
4
5
-3
-4
-5
6
-20
7
-7
-8
9
10
-9
-10
coefficient
coefficient
-40
-1 0
-6
8
-30
-2
M
M
23
What is Quantum Tunneling of the Magnetization (QTM)?
• The eigenstates are now |MS>+|-MS> and |MS>-|MS>.
• The splitting between them is called tunnel splitting (∆).
• In a static picture one can say that the system is located both on the left and right of the
energy barrier.
• In a dynamic picture one can say that the system oscillates coherently between the two
sides at a frequency which is equal to the tunnel splitting, until coupling to the environment
destroys coherence.
• The tunnel splitting in SMM is very small.
• The magnetisation can tunnel but only incoherently.
0 01
2
–1
Energy (cm )
-10
3
4
5
-3
-4
-5
6
-20
-40
-1 0
-6
7
-7
8
-30
-2
-8
9
10
-9
-10
∆
24
What is Quantum Tunneling of the Magnetization (QTM)?
There are three ways that the magnetisation can invert.
1. Thermal relaxation
2. Thermally- (phonon-) assisted tunneling
3. Ground state tunneling.
thermal relaxation
0 01
2
–1
Energy (cm )
-10
-3
-4
-5
3
4
5
6
-20
-40
-1 0
-6
7
8
-30
-2
9
10
thermally
assisted
quantum
tunneling
ground state
quantum tunneling
-7
-8
-9
-10
25
What is Quantum Tunneling of the Magnetization (QTM)?
M
10
0
-1
Energy (cm )
-10
-20
10
-5
-30
-6
-40
-7
-50
-8
-60
-9
-70
When a longitudinal field is applied, the spin
microstates change energy according to
the Zeeman interaction.
-10
-80
-3
-2
-1
0
1
2
3
At certain levels the microstates cross.
Magnetic Field (T)
The transverse anisotropy mixes the MS
levels at those fields making tunneling of
the magnetisation possible
0.020
0.015
0.010
1.8 K
2.0 K
2.2 K
2.4 K
2.6 K
4.2 K
M (emu)
0.005
0.000
-0.005
-0.010
-0.015
-0.020
-30000 -20000 -10000
0
H / Oe
10000 20000 30000
26
What is Quantum Tunneling of the Magnetization (QTM)?
6
-20
-6
7
-7
8
-30
-40
-8
9
10
0
-10
-10
-1
-1
-3
-4
-5
3
4
5
0
-1 0
Energy (cm )
–1
Energy (cm )
-10
-2
Energy (cm )
0 01
2
-20
-30
-20
-30
-9
-40
-40
-50
-50
-10
In the double well picture :
•
At zero field, the M levels on the left and right are in resonance.
•
Application of a magnetic field lifts this degeneracy.
•
At a certain field levels on the left and right come into resonance again.
27
What is Quantum Tunneling of the Magnetization (QTM)?
0
285 min
Transmission
10
10
75 min
-1
t=0
2
3
B=-0.9 T
-2
B=0.9 T
M
10
1
Mn12Ac
10
-3
B=0
8
M
T=1.96 K
d=1.39 mm
Points - exper.
Lines - theory
9
10
11
-1
Frequency (cm )
Dressel et al., PRB, 2003
12
Relaxation time (s)
10
We were able to see QTM also spectroscopically:
• At zero field, the magnetic resonance line of a
powder sample of Mn12Ac lies at ~10 cm-1 [1].
• In a field cooled sample, the line broadens and
shifts to higher frequency [2].
• On reversing the field, the system ends up in a
metastable state [3].
• Some molecules experience a longitudinal field
such that QTM occurs and a tunnel dip forms in
the spectra.
5
10
4
10
3
10
2
T = 1.96 K
H = 0.9 T
4,-5
9,-10
8,-9
7,-8
6,-7
5,-6
Mn12ac
0.0
0.2
0.4
0.6
cos θH
0.8
1.0
28
What is Mesoscopic
Quantum Coherence?
29
What is Mesoscopic Quantum Coherence (MQC)?
•
Macroscopic Quantum Coherence is realised when quantum tunneling between
energetically degenerate and macroscopically different states occurs at a rate which
is large compared to the decoherence rate
•
Another view is that the energy eigenstates are coherent superpositions of states
which are macroscopically different.
•
Mesoscopic is used here to indicate the scale between microscopic and true
macroscopic phenomena.
30
What is Mesoscopic Quantum Coherence (MQC)?
•
•
•
•
The zero field tunnel splittings in high spin clusters are generated by transverse
crystal field splitting.
They are small:
• Ground state tunnel splitting (∆) in Mn12Ac: ∆/kB ~ 10-10 - 10-11 K.
• Tunnel splitting is larger for higher M states:
M = ±4, ∆/kB = 10-2 K; M = ±2, ∆/kB = 0.7K.
• In Fe8, ground state tunnel splitting perhaps 10-7 K.
The main sources of decoherence are intermolecular dipolar interactions (0.1 K) and
hyperfine interactions (0.01 - 0.1 K).
Application of a transverse magnetic field leads to an increase in the tunnel splitting.
31
What is Mesoscopic Quantum Coherence (MQC)?
•
•
•
On application of a transverse magnetic field the tunnel splitting can be made larger
than sources of decoherence,.
If the field is large enough it may be observed in experiment.
This is sometimes taken as proof for the occurrence of MQC.
HFEPR:
Hill et al., cond-mat/0302052
Specific heat:
Mettes et al., PRB, 2001
Luis et al., PRL, 2000
32
What is Mesoscopic Quantum Coherence (MQC)?
•
•
•
•
•
In antiferromagnetic systems the spin
dynamics are governed by the exchange
interaction.
In these cases tunnel splittings can easily
be made larger than the sources of
decoherence.
Furthermore because of the small net
magnetic moment, coupling to the
environment is small.
The first experimental claims of MQC were
made on ferritin, a naturally occurring
antiferromagnetic system.
MQC is observed as coherent tunneling of
the Neel vector.
Gider et al., Science, 1995
33
What is Mesoscopic Quantum Coherence (MQC)?
•
•
•
•
•
•
In antiferromagnetic rings with an
even number of paramagnetic ions
the total spin is S = 0.
The ground state is the
superposition of the two Neel states.
On tunneling of the Neel vector, the
net magnetic moment does not
change
Therefore a local probe is needed
which couples to the oscillations of
the Neel vector (NMR).
Another solution is to replace one of
the spins by different one, to create
a net magnetic moment.
In that case EPR can be used to
observe the tunneling of the Neel
vector.
Meier, Loss, PRL 2001, PRB, 2001
34
What is Mesoscopic Quantum Coherence (MQC)?
• Recently, a single molecule magnet was reported
that consists of two molecules that are weakly
superexchange coupled in the crystal.
• The used abbreviation is [Mn4]2.
• The exchange interaction shifts the steps in the
magnetic hysteresis curve.
Wernsdorfer et al., Nature 2002
35
What is Mesoscopic Quantum Coherence (MQC)?
• Due to the weak exchange interaction
(J ~ 0.1 cm-1), the system behaves as
two exchange coupled S = 9/2 spins.
• This leads to the absence of a level
crossing at zero field.
36
What is Mesoscopic Quantum Coherence (MQC)?
• The HFEPR spectrum shows a much more complicated pattern than monomeric
derivatives of Mn4.
• Since the energy splittings are much larger than possible sources of decoherence,
this was claimed as an observation of mesoscopic quantum coherence.
Hill et al., Science 2003
37
What is the Berry
Phase?
38
What is the Berry Phase?
Any ''vector'' object which is parallel
transported along a path back to the
original place, may acquire an angle
with respect to its initial direction prior to
transport. This angle is a geometric
property.
A phase change can occur when the
surface along which the vector object is
transported is not flat.
No phase change is observed when the
vector object is transported along a flat
surface.
39
What is the Berry Phase?
easy axis
The magnetic moment is preferentially oriented
along the easy axis, i.e. the z axis
In the xy plane it has a preference for the
intermediate or y axis.
θ
In order to invert, the magnetic moment can
choose two pathways, clockwise and anticlockwise
in a plane parallel to the yz plane.
intermediate
axis
The two paths lead to different acquired phases.
Applying a magnetic field along the hard axis tilts
the magnetic moment towards the hard axis.
hard axis
e.g. Fe8
The acquired phases on reversal change with the applied field.
For some magnetic fields the acquired phases are opposite and the tunneling probability
becomes zero due to their interference.
40
What is the Berry Phase?
z
For a magnetic field component along the
intermediate axis there is only one tunneling path.
A
Hence there is no interference.
y
ϕ
B
x
41
Energy
Energy
What is the Berry Phase?
0
40
Intermed
80
iate axis
120
160
angle (°)
-80
-40
H
a rd
0
Ax
40
80
ng
is a
le
( °)
0
40
Intermed
80
iate axis
120
( °)
160
-80
-40
0
Ha
rd
40
s
a xi
The tunneling path is that which passes the
lowest barrier, i.e. it minimises the classical
action
42
80
(°)
What is the Berry Phase?
The occurence of periodic quenching of the
tunnel splitting was experimentally observed in
Fe8 by a method known based on LandauZener tunneling.
For smaller sweep rates the system has more
time to relax to the ground state.
6
Bx=1T
3
-1
E [cm ]
4
mS=+1/2
2
10
8
6
4
2
-2
-4
-6
-8
-10
Bz [T]
-2
mS=-1/2
mS=+1/2
-4
1
-6
⎧⎪
⎫⎪
π ∆2
W13 = exp ⎨−
⎬
⎪⎩ 4hg µ B S (dBz / dt ) ⎪⎭
2
Wernsdorfer, Sessoli, Science, 1999
43
What is the Berry Phase?
easy axis
This effect can also occur in Mn12Ac.
Since the symmetry is tetragonal, the x- and yaxes are both intermediate axes.
The hard axis lies along the bisecting line.
θ
intermediate
axis
intermediate axis
hard axis
44