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Quantum effects in Magnetic Salts

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Christensen (PSI) H. Ronnow (PSI) D. McMorrow (LCN) S.M. Hayden (Bristol) R. Coldea (Bristol) ... Christensen et al, unpub (2006) ... – PowerPoint PPT presentation

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Title: Quantum effects in Magnetic Salts

1
Quantum effects in Magnetic Salts

G. Aeppli (LCN)
N-B. Christensen (PSI)
H. Ronnow (PSI)
D. McMorrow (LCN)
S.M. Hayden (Bristol)
R. Coldea (Bristol)
T.G. Perring (RAL)
Z.Fisk (UC)
S-W. Cheong (Rutgers)
Harrison (Edinburgh)
et al.

2
outline

Introduction salts?quantum mechanics?classical
magnetism
RE fluoride magnet LiHoF4 model quantum phase
transition
1d model magnets
2d model magnets Heisenberg Hubbard models

3
Experimental program

Observe dynamics
Is there anything other than Neel state
and spin waves?
Over what length scale do quantum degrees of
freedom matter?

4
Pictures are essential cant understand nor use
what we cant visualize-difficulty is that
antiferromagnet has no external field-need
atomic-scale object which interacts with spins

Subatomic bar magnet neutron
Atomic scale light X-rays

5
Scattering experiments
kf,Ef,sf
ki,Ei,si
Qki-kf hwEi-Ef
Measure differential cross-sectionratio of
outgoing flux per unit solid angle and energy to
ingoing fluxd2s/dWdw
6
inelastic neutron scatteringFermis Golden Rule

at T0,
d2s/dWdwSfltfS(Q)0gt2d(w-E0Ef) where S(Q)
SmSmexpiq.rm
for finite T
d2s/dWdw kf/ki S(Q,w) where S(Q,w)(n(w)1)Imc(
Q,w)
S(Q,w)Fourier transform in space and time of
2-spin correlation function
ltSi(0)Sj(t)gt
Int dt Sij expiQ(ri-rj)expiwt ltSi(0)Sj(t)gt

7
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8
ISIS Spallation Neutron Source
9
ISIS - UK Pulsed Neutron Source
10
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11
Information
576 detectors 147,456 total pixels 36,864
spectra 0.5Gb
Typically collect 100 million data points
12
The Samples
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14
Two-dimensional Heisenberg AFM is stable for
S1/2 square lattice
15
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16
Copper formate tetrahydrate
2D XRD mapping (still some texture present
because crystals have not been crushed fully)
Crystallites (copper carbonate formic acid)
17
H. Ronnow et al. Physical Review Letters 87(3),
pp. 037202/1, (2001)
18

Copper formate tetradeuterate

19
Christensen et al, unpub (2006)
20
(p,0) (3p/2,p/2) (p,p)
Christensen et al, unpub (2006)
21
Why is there softening of the mode at (p,0) ZB
relative to (3p/2,p/2) ?

Neel state is not a good eigenstate
0gtNeelgt SaiNeel states with 1 spin flippedgt
SbiNeel states with 2 spins flippedgt
real space basis entanglement
0gtNeelgtSkakspin wave with momentum kgt
momentum space basis
What are consequences for spin waves?

22
Neelgt
correctiongt
0gt
whereas flips along (0,p) and (p,0) cost 4J,2J
or 0 e.g. -
All diagonal flips along diagonal still cost 4J
SWgt
?SW energy lower for (p,0) than for (3p/2,p)
C. Broholm and G. Aeppli, Chapter 2 in "Strong
Interactions in Low Dimensions (Physics and
Chemistry of Materials With Low Dimensional
Structures)", D. Baeriswyl and L. Degiorgi,Eds.
Kluwer ISBN 1402017987 (2004)
23
How to verify?

Need to look at wavefunctions
info contained in matrix elements ltkSk0gt
measured directly by neutrons

24
Christensen et al, unpub (2006)
25
Spin wave theory predicts not only energies, but
also ltkSk0gt
Christensen et al, unpub (2006)
26
Discrepancies exactly where dispersion deviates
the most!
Christensen et al, unpub (2006)
27
Another consequence of mixing of classical
eigenstates to form quantum states-

multimagnon continuum
Sk0gtSkakSkkgt
Skakk-kgt
?many magnons produced by Sk
?multimagnon continuum
Can we see?

28
Christensen et al, unpub (2006)
29
Christensen et al, unpub (2006)
30
Christensen et al, unpub (2006)
31
2-d Heisenberg model

Ordered AFM moment
Propagating spin waves
Corrections to Neel state (aka RVB, entanglement)
seen explicitly in
Zone boundary dispersion
Single particle pole(spin wave amplitude)
Multiparticle continuum

Theory Singh et al, Anderson et al
32
Now add carriers but still keep it insulating

Is the parent of the hi-Tc materials really a
S1/2 AFM on a square lattice?

33
2d Hubbard model at half filling
non-zero t/U, so charges can move around still
antiferromagnetic why?
34
gt
...

gt
t2/UJ
gt
t0
t nonzero
FM and AFM degenerate
FM and AFM degeneracy split by t
35

consider case of La2CuO4 for which t0.3eV and
U3eV from electron spectroscopy,
but ordered moment is as expected for 2D
Heisenberg model

R.Coldea, S. M. Hayden, G. Aeppli, T. G. Perring,
C. D. Frost, T. E. Mason, S.-W. Cheong, Z. Fisk,
Physical Review Letters 86(23), pp. 5377-5380,
(2001)
36
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38
(p,p) (p,0) (3p/2,p/2)
(3p/2,p/2) (p,0) (p,p)
39
Why? Try simple AFM model with nnn interactions-
? Most probable fits have ferromagnetic J
40
ferromagnetic next nearest neighbor coupling

not expected based on quantum chemistry
are we using the wrong Hamiltonian?
consider ring exchange terms which provide much
better fit to
small cluster calculations and explain light
scattering anomalies , i.e. HSJSiSjJcSiSjSkSl

Si
Sl
Sj
Sk
41
R.Coldea et al., Physical Review Letters 86(23),
pp. 5377-5380, (2001)
42
Where can Jc come from?
Girvin, Mcdonald et al, PRB
From our NS expmts-
43
Is there intuitive way to see where ZB dispersion
comes from?
C. Broholm and G. Aeppli, Chapter 2 in "Strong
Interactions in Low Dimensions (Physics and
Chemistry of Materials With Low Dimensional
Structures)", D. Baeriswyl and L. Degiorgi,Eds.
Kluwer ISBN 1402017987 (2004)
44
For Heisenberg AFM, there was softening of the
mode at (1/2,0) ZB relative to (1/4,1/4)
Neelgt
correctiongt
0gt
whereas flips along (0,1) and (1,0) cost 4J,2J
or 0 e.g. -
All diagonal flips along diagonal still cost 4J
SWgt
45
Hubbard model- hardening of the mode at (1/2,0)
ZB relative to (1/4,1/4)
Neelgt
correctiongt
0gt
whereas flips along (0,1) cost 3J or more because
of electron confinement
flips along diagonal away from doubly occupied
site cost lt3J
SWgt
46
summary