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Frustration in highly random magnetic systems
2145
Physica 109 & 1lOB (1982) 2145-2147 North-Holland Publishing Company
FRUSTRATION R.N.
IN HIGHLY
RANDOM
MAGNETIC
SYSTEMS
BHA-IT
Bell Laboratories, Murray Hill, N.J. 07974, USA A numerical method is used to investigate the scaling behavior of positionally random king and quantum Heisenberg spin l/2 systems in two and three dimensions with short range antiferromagnetic interactions. A study of the distribution of couplings, as high-lying states of the system are eliminated, exhibits qualitatively different behavior in the two cases. This bears upon the possibility of frustration and spin-glass freezing in these systems at low temperature.
the
1. Introduction
scene.
range Recent
experiments
semiconductors, romagnetic failed
a positionally
3d Heisenberg
to detect
tibility related
[l) on insulating
n-doped
random
any cusp in the magnetic
(spin-glass magnetic
antifer-
spin l/2 system,
have
suscep-
behavior) or other exchangeordering. This is despite going
down to very low temperatures (-5 mK), much below the median nearest neighbour exchange or the bare
exchange
percolation
naively some kind of expected [2] to develop results
can be explained
basis of numerical how spin
the
l/2 system
conventional cluster
in three
on the
[3], which show
dimensions which
have been
below down
the
median
to where
spins have been frozen the Curie value) [3].
orders
of
near-neighbour
almost
99%
(susceptibility
of the = 1% of
2. Scaling procedure In order
to confirm
the importance
(the large
condensation
tum
effects
inert
character
of singlets)
of quanenergy
in the highly
and
random
netic
from
do not allow so successful quantum
Heisenberg spin and the high dis-
order - i.e., near-neighbour exchange couplings differing by orders of magnitude, pairs (or clusters) of strongly coupled spins have a large condensation energy. Thus, as the temperature is lowered, the strongly coupled parts of the system condense into inert singlets, with a very small polarizability, and effectively “disappear” from 0378-4363/82/0000-0000/$02.75
magnitude coupling,
for temperatures
differs
in fitting the experimental data [l, 21. The crucial point is the extreme nature of the antiferromagnetic l/2 system. Because of this
paramagnetic
of long-
and the system
system, similar scaling calculations have been performed for the corresponding antiferromag-
[4] and also why simple
[l, 2,5]
remains
generation
or correlations
Heisenberg
quantum
spin glasses freezout
successfully
studies
random
calculations
for a spin-glass
quite
suppresses
where
“frustration” may be in the system. These
scaling
highly
threshold,
This
interactions
@ 1982 North-Holland
Ising
The starting positioned
system
in two and three
dimensions.
point is a system of up to 10 000 spins randomly
in a d-dimensional
cube
(not on lattice sites, but a continuum, like the Heisenberg system appropriate for doped semiconductors) with periodic boundary conditions, with a Hamiltonian:
H =
C
J(r;,)SiSj
I-Cj
where with
romagnetic moments.
p;S;
1
I
Si take J(r)
+h C
on the values
= Jo exp(-2rla)
t1/2,
and to start
is uniformly
antifer-
(J > 0) and ,u, = 1 are the magnetic The system is thus characterized by a
2146
R.N.
single
dimensionless
c = nad, where
bonds
up to a fixed,
Typically is analogous
Heisenberg
system,
high-lying sidering
excited
pair;
Ising
remaining
represented magnetic
two
by a single moment (where
the couplings) (Jjc- J,(). This arbitrary couplings within
by con-
means of the
can
then
be
Sk = l/2
with
the
couplings
of the
e of i and j for the Ising
the eigenvalues
is easily procedure
system
this
configurations spin
where
of the
pair of spins (a j)
states
pk = 0. The
new spin k to neighbours Hamiltonian
removal
case),
are linear
shown to in general
in
be Jkl = generates
magnetic moments and sign of the Jkp; however, the Hamiltonian remains
the Ising spin
l/2 subspace
x exp[-fdc h^($)],
fol-
quantum
at each stage. For the initial
of the two parallel the
the
(eq. (1)). The
generalization of the above formulae arbitrary decimation in the procedure
systems
P”
are
procedure
for
magnetic
up to 50
of the system
coupled
antiferromagnetic
removal
keeping
scaling that
states
of spins.
low, threshold
i.e. systematic
the strongest
in the system (the
to
in highly random
parameter
density
this means
for each spin. The
lowed
I Frustration
concentration
n is the actual
All couplings retained.
Bhatt
for an followed
is:
c = nad, and fd is a numerical
depending
on the dimensionality
(f, = I, fi = ~14, f3 = 7r/6). As the system is scaled, the maximum coupling is reduced in magnitude, and the distribution of nearest “nearest
neighbour neighbour”
couplings coupling
given stage of the scaling the width
largest
coupling
of the
scale alluded
=
Pi -
sign(A,)pj.
Jkp = J;, - sign(Jij))J,r, where
J >O
(ferromagnetic)
(CO) refers
to
procedure
distribution
as
spin).
the
logarithmic
(on
to), W, is a measure
The
of the disorder
is given by Wo = [r(l + 2/d) W” P(1 + l/d)]“2/(fcd)1’d. Fig. l(a) shows the variation of W as a function of the maximum coupsee ref. 3) J,,,,,, for the Ising
ling (temperature,
as well as the quantum
Heisenberg
as the system
The distribution
is scaled.
dramatically
(2b)
quantum practically
Heisenberg invariant.
is a direct
consequence
coupling.
is defined
that
(and frustration) in the system - the larger the W, the more disordered the system, and less likely the spins are to be frustrated. The initial width
(24
antiferromagnetic
also changes (the of any spin at any
involving
lings for the Ising system E*k
constant
of the system
with
the latter-the
system
in 2d
of coup-
can be seen to narrow
scaling,
in
contrast
to
the
system, where it remains This difference in behavior
freezing
of the quantum of pairs
nature
or clusters
of into
singlets effectively removes the coupling between them and the remaining spins even though the
3. Results and discussion
bare interaction may be large compared to the interactions among the remaining spins. The Ising clusters, on the other hand (though they may
The initial system for values of c appropriate for doped semiconductors has a very wide distribution of near neighbour exchange couplings, extending over several orders of magnitude in J [l-3]. Consequently, it is convenient to look at the distribution of the logarithm of the nearestneighbour coupling P(ln Jo/J) which, for the initial system, is given by
themselves be predominantly magnetically inert (j..~= 0) for the antiferromagnetic case), have a degenerate ground state (corresponding to flipping of all spins in the cluster). This enables them to serve as a communicating medium for interactions among the more weakly coupled spins. Thus, the Ising system does not have the “exchange dilution” property [2] of the quantum Heisenberg system, and is therefore unable to
R.N.
1
(0)
10
2 D!MENSIONS
Rhatt
I Frustration
‘2’.
l
random
Y
0.0
map&
7147
systems
10-l -
(C=OOB) .
?
in highly
~POQ
fi
c!*o.o*&V aQP
1;
‘I0
&Q 1o-2 A.
05
- ISING
O.-QUANTUM HEISENBERG
10-3 I
0 p
IO.5
I
1o-4
10-J
I
I
lo-2
10-l
1
lo-
lb)
3 DIMENSIONS
(C=OO41
0 ? ;:
D
\ \ \
,E 10-4 -
a
a
\
1
\ \
.
.
--
3d ISING ---
-__
\
‘\
n a -ISING
‘\
10-5 -
0 -QUANTUM HEISENBERG
‘\
HEISENBERG \ ‘,
o10-4
‘\. 40-e 0 10-3
10-z
10-l
I
1
10
20
1
-. -
J
30
ff’
Jmax’Jo
Fig. I. Logarithmic width of the distribution versus maximum coupling (temperature) for Heisenberg and king systems in 2d and 3d.
of couplings the quantum
Fig. 2. Maximum coupling as a function tion of the spins left for the two systems
of the inverse in 3d.
frac-
, escape scaled, to.
the development of frustration like its Heisenberg counterpart
This
evident
difference
Ising
explicitly
scaling
behavior
is
of frustration
in
hospitality where
for development
system
in 3d is demonstrated
in fig.
2 which
plots
the
this
the was
Aspen
Center
for
Physics,
written,
are
gratefully
ac-
knowledged.
more maximum
coupling in the scaled system versus f-’ (f is the fraction of original spins left). For the Ising system, the coupling strength no such behavior is evident
tends to “hang up”; for Heisenberg spins.
Acknowledgements
References 111 K. Andres,
R.N. Bhatt, P. Goalwin, T.M. Rice and R.E. Walstedt, Phys. Rev. B24 (1981) 244. 121 R.B. Kummer, R.E. Walstedt, S. Geschwind, V. Narayanamurti and G. Devlin, Phys. Rev. Lett. 40 (1978) 1098; J. Appl. Phys. 50 (1979) 1700. [31 R.N. Bhatt and P.A. Lee, J. Appl. Phys. 52 (IYXI) 1703: Phys. Rev. Lett. 48 (1982) 344. [41 V. Cannella PI R.N.
Helpful
of
also in 3d (fig. l(b)).
The potential the
in the
as it is appears
discussions
with
P.A.
Lee
and
the
Bhatt
and J.A. Mydosh, Phys. Rev. B6 (1972) 4220. and T.M. Rice, Phil. Mag. B42 (1980) 859.
Physica 109 & 1lOB (1982) 2145-2147 North-Holland Publishing Company
FRUSTRATION R.N.
IN HIGHLY
RANDOM
MAGNETIC
SYSTEMS
BHA-IT
Bell Laboratories, Murray Hill, N.J. 07974, USA A numerical method is used to investigate the scaling behavior of positionally random king and quantum Heisenberg spin l/2 systems in two and three dimensions with short range antiferromagnetic interactions. A study of the distribution of couplings, as high-lying states of the system are eliminated, exhibits qualitatively different behavior in the two cases. This bears upon the possibility of frustration and spin-glass freezing in these systems at low temperature.
the
1. Introduction
scene.
range Recent
experiments
semiconductors, romagnetic failed
a positionally
3d Heisenberg
to detect
tibility related
[l) on insulating
n-doped
random
any cusp in the magnetic
(spin-glass magnetic
antifer-
spin l/2 system,
have
suscep-
behavior) or other exchangeordering. This is despite going
down to very low temperatures (-5 mK), much below the median nearest neighbour exchange or the bare
exchange
percolation
naively some kind of expected [2] to develop results
can be explained
basis of numerical how spin
the
l/2 system
conventional cluster
in three
on the
[3], which show
dimensions which
have been
below down
the
median
to where
spins have been frozen the Curie value) [3].
orders
of
near-neighbour
almost
99%
(susceptibility
of the = 1% of
2. Scaling procedure In order
to confirm
the importance
(the large
condensation
tum
effects
inert
character
of singlets)
of quanenergy
in the highly
and
random
netic
from
do not allow so successful quantum
Heisenberg spin and the high dis-
order - i.e., near-neighbour exchange couplings differing by orders of magnitude, pairs (or clusters) of strongly coupled spins have a large condensation energy. Thus, as the temperature is lowered, the strongly coupled parts of the system condense into inert singlets, with a very small polarizability, and effectively “disappear” from 0378-4363/82/0000-0000/$02.75
magnitude coupling,
for temperatures
differs
in fitting the experimental data [l, 21. The crucial point is the extreme nature of the antiferromagnetic l/2 system. Because of this
paramagnetic
of long-
and the system
system, similar scaling calculations have been performed for the corresponding antiferromag-
[4] and also why simple
[l, 2,5]
remains
generation
or correlations
Heisenberg
quantum
spin glasses freezout
successfully
studies
random
calculations
for a spin-glass
quite
suppresses
where
“frustration” may be in the system. These
scaling
highly
threshold,
This
interactions
@ 1982 North-Holland
Ising
The starting positioned
system
in two and three
dimensions.
point is a system of up to 10 000 spins randomly
in a d-dimensional
cube
(not on lattice sites, but a continuum, like the Heisenberg system appropriate for doped semiconductors) with periodic boundary conditions, with a Hamiltonian:
H =
C
J(r;,)SiSj
I-Cj
where with
romagnetic moments.
p;S;
1
I
Si take J(r)
+h C
on the values
= Jo exp(-2rla)
t1/2,
and to start
is uniformly
antifer-
(J > 0) and ,u, = 1 are the magnetic The system is thus characterized by a
2146
R.N.
single
dimensionless
c = nad, where
bonds
up to a fixed,
Typically is analogous
Heisenberg
system,
high-lying sidering
excited
pair;
Ising
remaining
represented magnetic
two
by a single moment (where
the couplings) (Jjc- J,(). This arbitrary couplings within
by con-
means of the
can
then
be
Sk = l/2
with
the
couplings
of the
e of i and j for the Ising
the eigenvalues
is easily procedure
system
this
configurations spin
where
of the
pair of spins (a j)
states
pk = 0. The
new spin k to neighbours Hamiltonian
removal
case),
are linear
shown to in general
in
be Jkl = generates
magnetic moments and sign of the Jkp; however, the Hamiltonian remains
the Ising spin
l/2 subspace
x exp[-fdc h^($)],
fol-
quantum
at each stage. For the initial
of the two parallel the
the
(eq. (1)). The
generalization of the above formulae arbitrary decimation in the procedure
systems
P”
are
procedure
for
magnetic
up to 50
of the system
coupled
antiferromagnetic
removal
keeping
scaling that
states
of spins.
low, threshold
i.e. systematic
the strongest
in the system (the
to
in highly random
parameter
density
this means
for each spin. The
lowed
I Frustration
concentration
n is the actual
All couplings retained.
Bhatt
for an followed
is:
c = nad, and fd is a numerical
depending
on the dimensionality
(f, = I, fi = ~14, f3 = 7r/6). As the system is scaled, the maximum coupling is reduced in magnitude, and the distribution of nearest “nearest
neighbour neighbour”
couplings coupling
given stage of the scaling the width
largest
coupling
of the
scale alluded
=
Pi -
sign(A,)pj.
Jkp = J;, - sign(Jij))J,r, where
J >O
(ferromagnetic)
(CO) refers
to
procedure
distribution
as
spin).
the
logarithmic
(on
to), W, is a measure
The
of the disorder
is given by Wo = [r(l + 2/d) W” P(1 + l/d)]“2/(fcd)1’d. Fig. l(a) shows the variation of W as a function of the maximum coupsee ref. 3) J,,,,,, for the Ising
ling (temperature,
as well as the quantum
Heisenberg
as the system
The distribution
is scaled.
dramatically
(2b)
quantum practically
Heisenberg invariant.
is a direct
consequence
coupling.
is defined
that
(and frustration) in the system - the larger the W, the more disordered the system, and less likely the spins are to be frustrated. The initial width
(24
antiferromagnetic
also changes (the of any spin at any
involving
lings for the Ising system E*k
constant
of the system
with
the latter-the
system
in 2d
of coup-
can be seen to narrow
scaling,
in
contrast
to
the
system, where it remains This difference in behavior
freezing
of the quantum of pairs
nature
or clusters
of into
singlets effectively removes the coupling between them and the remaining spins even though the
3. Results and discussion
bare interaction may be large compared to the interactions among the remaining spins. The Ising clusters, on the other hand (though they may
The initial system for values of c appropriate for doped semiconductors has a very wide distribution of near neighbour exchange couplings, extending over several orders of magnitude in J [l-3]. Consequently, it is convenient to look at the distribution of the logarithm of the nearestneighbour coupling P(ln Jo/J) which, for the initial system, is given by
themselves be predominantly magnetically inert (j..~= 0) for the antiferromagnetic case), have a degenerate ground state (corresponding to flipping of all spins in the cluster). This enables them to serve as a communicating medium for interactions among the more weakly coupled spins. Thus, the Ising system does not have the “exchange dilution” property [2] of the quantum Heisenberg system, and is therefore unable to
R.N.
1
(0)
10
2 D!MENSIONS
Rhatt
I Frustration
‘2’.
l
random
Y
0.0
map&
7147
systems
10-l -
(C=OOB) .
?
in highly
~POQ
fi
c!*o.o*&V aQP
1;
‘I0
&Q 1o-2 A.
05
- ISING
O.-QUANTUM HEISENBERG
10-3 I
0 p
IO.5
I
1o-4
10-J
I
I
lo-2
10-l
1
lo-
lb)
3 DIMENSIONS
(C=OO41
0 ? ;:
D
\ \ \
,E 10-4 -
a
a
\
1
\ \
.
.
--
3d ISING ---
-__
\
‘\
n a -ISING
‘\
10-5 -
0 -QUANTUM HEISENBERG
‘\
HEISENBERG \ ‘,
o10-4
‘\. 40-e 0 10-3
10-z
10-l
I
1
10
20
1
-. -
J
30
ff’
Jmax’Jo
Fig. I. Logarithmic width of the distribution versus maximum coupling (temperature) for Heisenberg and king systems in 2d and 3d.
of couplings the quantum
Fig. 2. Maximum coupling as a function tion of the spins left for the two systems
of the inverse in 3d.
frac-
, escape scaled, to.
the development of frustration like its Heisenberg counterpart
This
evident
difference
Ising
explicitly
scaling
behavior
is
of frustration
in
hospitality where
for development
system
in 3d is demonstrated
in fig.
2 which
plots
the
this
the was
Aspen
Center
for
Physics,
written,
are
gratefully
ac-
knowledged.
more maximum
coupling in the scaled system versus f-’ (f is the fraction of original spins left). For the Ising system, the coupling strength no such behavior is evident
tends to “hang up”; for Heisenberg spins.
Acknowledgements
References 111 K. Andres,
R.N. Bhatt, P. Goalwin, T.M. Rice and R.E. Walstedt, Phys. Rev. B24 (1981) 244. 121 R.B. Kummer, R.E. Walstedt, S. Geschwind, V. Narayanamurti and G. Devlin, Phys. Rev. Lett. 40 (1978) 1098; J. Appl. Phys. 50 (1979) 1700. [31 R.N. Bhatt and P.A. Lee, J. Appl. Phys. 52 (IYXI) 1703: Phys. Rev. Lett. 48 (1982) 344. [41 V. Cannella PI R.N.
Helpful
of
also in 3d (fig. l(b)).
The potential the
in the
as it is appears
discussions
with
P.A.
Lee
and
the
Bhatt
and J.A. Mydosh, Phys. Rev. B6 (1972) 4220. and T.M. Rice, Phil. Mag. B42 (1980) 859.