- Email: [email protected]
A phenomenological phase transition model for heavy particles
~
Solid State Conmunlcatlons, Printed in Great Britain.
Vol. 71, No. 8, pp. 637-641,
1989.
0038-I098/8953.00+.00 Pergamon Press plc
A P H E N O M E N O L O G I C A L P H A S E TRANSITION M O D E L FOR HEAVY PARTICI~S
B. BARBARA and S. ZEMIRLI Laboratoire
Louis N4el, CNRS,
166X, 38042 Grenoble Cedex France Received
: September 19 th 1989
In revised form : April 3 rd 1989 by P. Burlet.
We provide thermodynamical heavy
fermions
supposed
to
a phenomenological and
transport
model
for
properties
of
in w~ich the coherence
be
the
analog
of
the
length is
correlation
length in a phase transition occuring at zero Kelvin. Many consequences are derived which can be tested experimenzally. Although has
been
active
the problem
for
several
investigations,
of heavy
years
the
it
still
is
being understood. In particular, difficults to find a link between experiments experiments.
and
also
heavy a
which
model,
based
different
with
on
the
at T - 0 to link as
for
the
and
strong analogy
effects
coupling. with
of
some
kind
These each
interferences
of
involve
wave
coupled,
last are therefore other
through
indirectly
their
in a
coupled
interaction
In the simplest
a
specific
i).
atomic
phase
electrons
in as
heat,
with
to the
case of two
TK is
2n
a
electrons
singlet
; the
it
total
angular
or
holes
(see
problem ; below function. this
TK,
~(T)
model
we
assume
phase
transition
occurring
at
zero
sites
Impurity")
is
related
to
temperature particle :
T
function
localized
sites
i).
Such
a
that
the
evolution of the coherence length ~(T) is similar to that of the correlation length in a
atomic
(T S TK), when the
is
must be a decreasing
~/a
between
be n~/a
here consider the case n - i, where N - ~/a is taken as the "coherence length" of our
involving
temperature
-
momentum
figure
diffused coherently) is fK ~ I/TK" Therefore, the spheres of radius ~K of neighbouring impurities overlap incoherently with each interactions
N
"propagating Kondo singlet" might be considered as a boson for two electrons and as n coupled bosons for 2n electrons (with n > i). We shall
such a phase transition critical will be only associated with contributions.
At lower
will
involving
only for an even number of correlated
In
At high temperatures (T Z TK, where Kondo temperature) a Kondo lattice
For to
sites
conserved
Kelvin, allows us, many experiments
susceptibility,
in
(figure
equivalent
generally described as an assembly of non-correlated impurities. The spatial extension of the singlet ground state of each impurity (where conduction electrons are
other.
now
more atomic sites per In other words N atomic
spin-density
spin density wave.
many other approaches.
magnetic
are
time dependant way, with conduction electrons.
This
impurities. This model is not a Fermi liquid model and in that sense it differs markely from
the
electrons
spins fluctuate coherently through the diffusion of conduction electrons leading to
a very simple
resistivity, de Haas-Van Alphen .... for heavy fermions at different temperatures, magnetic fields, pressure or with the addition of
is
constructive
includes more and conduction electron.
of
different
the conduction
in a coherent way between such spheres
several local magnetic moments. Therefore, when the temperature decreases each "Kondo impurity"
from
properties
in terms of coherence
lattice
transition principle,
far
it is very theories and
between
we provide
acco~mts
fermions
Kondo
subject
relevant,
diffused
electrons, this picture reduces to that of a Kondo singlet involving (~/a) atomuic sites 1
In this paper, model I
fermions
become
The binding
637
c
energy
Kelvin.
of a Kondo
of
impurity
("Giant a the
In
quantities non-linear
Kondo
characteristic size
of
the
A P H E N O M E N O L O G I C A L PHASE TRANSITION M O D E L FOR HEAVY P A R T I C L E S
638 T
= Tc(f)
c
have
O n the other hand, proportional
to
dimensionality where d =
the
i)
substituting
(i) the n u m b e r of such GKI b e i n g
f-d
(where
of a GKI
coherence
the
(4)
:
d is the E u c l i d i a n
F = f-D = ruD ~(TcT-I )
takes
place
a l o n g a line,
a
(5)
w h e r e T c = l ( ~ ) "dz - IA -v/~ and
I =
D----d ' ~ d z
impurity 2 of
We
size
is the
f.
identical
shall
same
as
r a p i d l y above, written
now
in
The to
scaling form function
that
of
admit
(6)
the phase
everything
scaling
function
of
the
(Tc/T).
need
F(TcT'I , hT °~°)
T vD
=
:
(7)
is
i.e. the free energy c a n be also we
a
In the p r e s e n c e of a m a g n e t i c f i e l d h
2
transition described
which
is
r e d u c e d K o n d o lattice t e m p e r a t u r e
F that
dimensionality,
introduce
i
f is
ref.
F = f-D, w h e r e f = T "u ~(AT "¢) (D is a n
effective
-
(2)
= Tf(Tc(f)T'1)
necessarily
a
above
~ must as
g i v e n for a "true" impurity.
is
that
c o n s e q u e n c e the free e n e r g y c a n b e w r i t t e n
:
Fi(f)
an
the
find
and
F(x )
not
we given
; in the s i m p l e s t case
F - ~-d Fi(f )
of
(2)
form
the free e n e r g y of the a s s e m b l y o f GKI
w i l l be
where
in
scaling
Vol. 71, No. 8
and therefore all the t h e r m o d y n a m i c a l v a r i a b l e s such as
the susceptibility,
etc.., can be d e d u c e d
to
the specific heat,
:
X = T -7 X(TcT-*),
C = T x'= C(TcT'X)
(8)
to pay the coast of our assumption,
scaling
function
and
A
a
characteristic
etc...
energy). Different As
for
critical flipping
the
slowing time ~
of the impurity c
= To
Here the
(~)dz
well-known down,
the
phenomenon
should increase w i t h
c
of
characteristic the size
:
limits
asymptotic f(x) = when
I +
T
~
x
TO
is
X
a
reciprocal
flipping
time
exchange
of
energy
(r 0 - h/A) and z is a dynamical exponent.
= A(~) -dz ; z > 0 a c
(4)
limits
easily,
even
field.
Since
heavy
fermions
x
<<
C/T
i.
-
In p a r t i c u l a r
T "~ f c '
T "~ c '
can
also
be
obtained very
in the p r e s e n c e of a m a g n e t i c we
are :
2
Dv
- ~
dealing with non magnetic
the o r d e r p a r a m e t e r ~ s h o u l d be
n e g a t i v e or null C o r r e l a t i v e l y the K o n d o e n e r g y is : T
for
=TcT,
(3)
characteristic the
o b t a i n e d f r o m the u s u a l -a - x for x > > I a n d
R = C/xT = T2(Du'l)etc... c
; z > 0
of
f(x)
+...
0,
Other
order
are
forms
=
- dv + i = ~ + fl - 7 + 2fl
with
(9) ~ 0, vdz = i It
is
worthwhile
noticing
that
these
exponents refer to T and T c (h - 0). N o w we can define the
same
way
as
for
an e f f e c t i v e mass,
the
flipping
time,
in by
i n t r o d u c i n g the e x p o n e n t p :
= mo (~)pD , p > 0
mc
m o is the effective by
an
isolated
extension
fK"
mass
Kondo
In
an
(i0)
of e l e c t r o n s d i f f u s e d impurity
ideally
of
rigid
spatial
picture
p
should be equal to u n i t y and in any case p > 0. Clearly
enough
our
quantity
;
propagates
it
electrons, heavy
"coherent FIGURE
I
and
particle
is
near
is
a
static
conduction
equivalent
a null
dominated the
not
with
therefore
(having
regime"
fluctuations
GKI
by
spin).
to
a
In
this
critical
spin
absolute
zero
of
Vol.
71, No. 8
temperature (i0) is :
A PHENOMENOLOGICAL
the
form
PHASE TRANSITION
of ~ to be substituted
= T -~ f(Tc T . 1) However this
regime
essentially nothing
can
also
use
when
spin
fluctuations
but
the
scale.
Kondo
(I0)
the
act
where
f
is
of assemblies
or "giant" resistivity
(a)
(~ > can
; P > 0
~K ) be
(13)
For
single
non- interacting
impurities,
the
number of particles is constant and equal to n o the number of Kondo sites ; furthermore the (12)
Note transitions
that our simple analogy with phase at zerc Kelvin indicate that T and c T K are connected to each other : T c = T K - A I. The expressions (ll) and (12) simply are the limits
near the phase
(ii)
and
well
characteristic
transition
above
time
for elastic
(12)
of
reflects
by
balistic collisions,
the
the
;
the
problem
"width
The scaling form of the for these two limits are then :
low
temperature
mK
=
regime
of
is the
affeetive
mass
(TcT-I , hT - ~ ° ) for the where
flipping
time z.
temperatures
f > fK'
and
(T ~ O) will not be time
T but by the c different site corresponds to
between This case
T < T K.
m A
(~a)-b .
f > f K ' p = Pc = ~ Since
Pc
must
decrease
GKI increases,
when
b=D(Z-p)-d
the
size
(14)
( of the
b > 0. In this case T = T . c
regime".
m c = mo T -pDv Mc
diffusions
the
at zero K e l v i n
it
temperature
simply
critical
classes
iP
m
< ~K' P = PK = ~
dominated
Tc
main
639
is
: = T-* ~ (TKT-I)
TK ;
two
of incoherent (f _< ~K ) Kondo impurities, the written in this model :
beyond
This regime
regime
For
in
(ii)
at the atomic
else
given by
one i.e.
MODEL FOR HEAVY PARTICLES
Using the forms of ~K(T) and ~(T) given above we deduce the scaling (and the low temperature limits) forms of the resistivity : Far of the critical
regime
:
(ii) PK ~ T'P PK (TKT-I)
m0 T'P
temperature mass
~(TKT-I, regime
increases
between
hT -4°)
where
when
for
~ S ~K"
the
the
PK ~ TKP
decreases
In the critical
:
For T = Te, m e = mo Tc-PDv
(15)
The effective
temperature
T K and T c. In particular
high
regime
:
Pc o~ T ub Pc (TcT-1) Pc a TUbc
and
(16)
(12) T = T K , m K = mo T K p The
other
limits
and field dependant
Well
which
are
temperature
can also be evaluated.
critical unitary
The
resistivity
impurity
is
given,
at
p - p0(l (T/TK)~) limit s . Our physical allows
an extension
in which the
the
size
of
v e r y different
low
single
Kondo
temperature,
of this Fermi liquid
o~
Kondo
a
by
limit GKI.
lattice
theory
is renormalized
to
Therefore,
the
is
approach
in
our
from a simple Fermi liquid.
number
of
heavy-particles
= lifetime
where
critical
where
the
depends
on
"~-renormalized the
temperature
the
~(x) - x -a - x -(a+2) length function
same +
asymptotic
form
... for the correlation
at Tc < T << T K and T << Tc :
p(T~T K) = p0(T K)
(I-P(~K)2+...)
(17)
= p0(T c) ( l + b ( ~ ) 2 - . . . ) c
(18)
and
and
- Zc(~) : flipping time of a GKI = time of cohereHt conduction of Kondo electrons within the heavy particle
regime limit"
Using
p(T~Tc)
where b and pd are both positive. The change of sign of the T 2 coefficient between a Fermi liquid
=
region
low
Starting from the simplest Boltzmann expression for the resistivity associated with a flow of particles p = m * /ne 2 r, we just put * m = mc(f) mass of an heavy-particle, n = (~)-d~
the
P0 ~ TVb~ (TcT-*)-
where P0 is the unitary picture for heavy fermions
unitary
~
temperature
of
above
effects are sizable, the system is in a Fermi liquid limit. This is no longer the case in the
of this particle.
near
TK
and
the
Kondo
lattice
near
T c = TK-A , is in this model simply due to the fact that in the latest the time of coherent (non dissipative) conduction within the "heavy particles" r = ~0 (~/a) Dz increases c
640
A PHENOMENOLOGICAL
dramatically well
when
Lelow
nothing spin
T K.
else
the
We
but
model
relate
quantities. to
critical
phase
write
are
the
quantum
transition
set it
this
check
of
b > 0,
(14),
a
the
moment
The
the
the T -I one
T
relative
the
effective mass w i t h temperature
Furthermore
our
which,
the correlation
in
=
0,
new
of
rate), (see
eq.
14).
always
is not
Many
our
experiments
;
the
3.
All
the
if we
From
our
This
(or holes) of
~,
origin
size the
or
electrons bounding might
of
f
b = 31
always
the number
volume =
values
of
exponent
~.
not
the
or
holes
mechanism
experiments the moment
phase
satisfied >
0.
(see
During
below
them
containning
the
scheme the
a
figure
2b)
renormalization
critical
of non correlated
volume b y the clusters)
divided
the inequality fd > (D
temperature,
moments
can be w r i t t e n
Vexcl = 1 - ~-[ D - 4 = 1 - t~ where
~ > 0, Vexcl
is an increasing
the
(a)
evaluated,
~
bounded
an
even
and
value
the following values
of
into a Kondo picture
cluster of
being
of
quantum
of
bounded
it
the
is
between
given
can give
d.
general
whatever is),
for
a pair
number
of our exponents
will be we
are
be
in which
fluctuations
any
staggered
the sample is schematically of
on the
usal
in
include
for
(in a more
to
take
at
initial
in r e l a t i o n
In
spatial
antiferromagnetic
due
determination
the
:
=included
negative
have b e e n done
might
a value picture,
into a fluctuating size
of
should therefore
does
exponents
assumed
starting
electrons
to length
dimensionality
of other contributions 4 .
now,
singlet
related
(excluded :
P0 a cb/s
effective
be
to
of
that Po a c (at least if c
of our clusters
equal
the
to I/T.
shall conclude by a d i s c u s s i o n
concept
magnetization
is
scattering
As a consequence
dimensionality existence
that
show a low
(21)
(see e.g. ref (i) and therein
large).
model
low value
A(fo/a) "2d
=
just
showing
too
the
process
in h e a v y fermions ref)
correlation
length should be limited to the
gives the residual resistivity
shows also
only
transitions
picture
diffusion
to C/T
term must
is
~
strong
a
limiting
the
because
(with
the
ratio
defects,
~D ~ c'Z/s where c is the c o n c e n t r a t i o n
defects
indicates to
into f-d boxes, each cluster of volume fD ; of
. c
A T s contribution
coupling, and
R
or pressure
presence
or
or the
value
changes
physical
the
example
(T T "2)
but proportional
v i r t u a l excitations
(d Ln mc/dT = d Ln mc/dT c = - pDu).
according
heat
for
X (TcT-=),
the
(19)
little
up
upturn,
Wilson
exchange
with
size
specific
We
only
(Tc/A)2e.
=
X0 =
constraint
i - ud + z P < I + wd therefore
R
susceptibility
Tr3/2,-
can
C/T - T "1 C
upturn
such as :
and
on
X = T-3
heat
temperature
The
we
concerning
mass-exponent
ratio
temperature
therefore
the
values
Vol. 71, No. 8
the
verifying
At
exponents.
implies
be
these
susceptibility
specific
linear
of the n o n proven
model 4.
these
now
with
and
only give some indications
values
will
exponents
relations
an a-posteri
measurable
comparison
the
Wilson
at
of exponents
many
that
by
different
of
a
other
believe
scaling
hypotheses shall
GKI
to
each
find,
experiments, proposed providing
a
provides
to We
possible
near
of
From
decreases
the
(for TK=~).
This which
that
clusters
fluctuations
zero Kelvin
temperature
recall
PHASE TRANSITION M O D E L FOR HEAVY PARTICLES
physical
clear i
and
that 3.
(b)
d
The
in relation with
in another
paper.
from the relations
l
At
(9),
:
= 0, Dv = i, 40 = i, 7 = i, dv = ~ << i = -I, Dv = I, 4o = 2, 7 = 3, d~ = ¢ << i
FIGURE 2
a
function of
A PHENOMENOLOGICAL PHASE TRANSITION MODEL FOR HEAVY PARTICLES
Vol. 71, No. 8
In the present model where ~ < O, the cluster volume fD is larger than the volume allowed by each bc,x ~d, leading to an overlap between different clusters (figure 2b), and consequently to a "cluster included volume" Vinci = I - El D-4
subjected to the destructive interference of overlapping clusters (it is clear that there is no phase coherence between different clusters).
which
dynamical
constant
;
volume of cluster cores in
correlations
the
core
f(fd-D-l)I/D.-
This
decrease
down
to
f'fcore'
which
are
size
correlation
zero
over
re]presents
essentially
is
~core
length
the distance
the
thickness
=
will
represents therefore
the ~ n increase
be
considered
can be very
as
particles
small
of
size
if ~ is large
(contrarily to the excluded volume of usual phase transitions the included volume is a decreasing function of f). In particular, we always have the inequality fcore << fK' the usual Kondo impurity spatial extension in a diluted system (without overlap). These bags of spin fluctuating coherently can be considered as "Kondo droplets" or more generally "spin fluctuating quantum droplets "I. They are a direct consequence of the negative value of the staggered magnetization exponent ~ (This point will be discussed in more details in ref 4).
6 = of a
continous transit:ion region of dynamical moments separing different clusters of coherent quantum fluctuations (dynamical domain wall characterized by a gradient of coherence of spin fluctuations). The total proportion of moments belonging to walls is ~ fD-d .
can
~core which
This volume measures the proportion of magnetic moments belonging to a given cluster and fluctuating coherently without being
Vinci represents ~ e
temperature decreases or the exchange interaction A increases (physically due to increasingly destructive interferences volumes associated with larger exchange couplings between localized sites). Clearly enough our CKI D
(22)
641
these quantum dynamical I ; this volume also fluctuating sites which with ~ i.e. when the
A C K N O ~ S
We are grateful to C.M. Varma who encouraged us to develop this model at the ICAREA conference and to C. Bastide, M. Cyrot and P. Stamp for their interest and critical remarks. More recently M. Papoular read in details our manuscript. He is gratefully acknowledged for his suggestions. We are also pleased to thank Drs J. Vannimenus and N. Ashcroft for interesting discussions.
Solid State Conmunlcatlons, Printed in Great Britain.
Vol. 71, No. 8, pp. 637-641,
1989.
0038-I098/8953.00+.00 Pergamon Press plc
A P H E N O M E N O L O G I C A L P H A S E TRANSITION M O D E L FOR HEAVY PARTICI~S
B. BARBARA and S. ZEMIRLI Laboratoire
Louis N4el, CNRS,
166X, 38042 Grenoble Cedex France Received
: September 19 th 1989
In revised form : April 3 rd 1989 by P. Burlet.
We provide thermodynamical heavy
fermions
supposed
to
a phenomenological and
transport
model
for
properties
of
in w~ich the coherence
be
the
analog
of
the
length is
correlation
length in a phase transition occuring at zero Kelvin. Many consequences are derived which can be tested experimenzally. Although has
been
active
the problem
for
several
investigations,
of heavy
years
the
it
still
is
being understood. In particular, difficults to find a link between experiments experiments.
and
also
heavy a
which
model,
based
different
with
on
the
at T - 0 to link as
for
the
and
strong analogy
effects
coupling. with
of
some
kind
These each
interferences
of
involve
wave
coupled,
last are therefore other
through
indirectly
their
in a
coupled
interaction
In the simplest
a
specific
i).
atomic
phase
electrons
in as
heat,
with
to the
case of two
TK is
2n
a
electrons
singlet
; the
it
total
angular
or
holes
(see
problem ; below function. this
TK,
~(T)
model
we
assume
phase
transition
occurring
at
zero
sites
Impurity")
is
related
to
temperature particle :
T
function
localized
sites
i).
Such
a
that
the
evolution of the coherence length ~(T) is similar to that of the correlation length in a
atomic
(T S TK), when the
is
must be a decreasing
~/a
between
be n~/a
here consider the case n - i, where N - ~/a is taken as the "coherence length" of our
involving
temperature
-
momentum
figure
diffused coherently) is fK ~ I/TK" Therefore, the spheres of radius ~K of neighbouring impurities overlap incoherently with each interactions
N
"propagating Kondo singlet" might be considered as a boson for two electrons and as n coupled bosons for 2n electrons (with n > i). We shall
such a phase transition critical will be only associated with contributions.
At lower
will
involving
only for an even number of correlated
In
At high temperatures (T Z TK, where Kondo temperature) a Kondo lattice
For to
sites
conserved
Kelvin, allows us, many experiments
susceptibility,
in
(figure
equivalent
generally described as an assembly of non-correlated impurities. The spatial extension of the singlet ground state of each impurity (where conduction electrons are
other.
now
more atomic sites per In other words N atomic
spin-density
spin density wave.
many other approaches.
magnetic
are
time dependant way, with conduction electrons.
This
impurities. This model is not a Fermi liquid model and in that sense it differs markely from
the
electrons
spins fluctuate coherently through the diffusion of conduction electrons leading to
a very simple
resistivity, de Haas-Van Alphen .... for heavy fermions at different temperatures, magnetic fields, pressure or with the addition of
is
constructive
includes more and conduction electron.
of
different
the conduction
in a coherent way between such spheres
several local magnetic moments. Therefore, when the temperature decreases each "Kondo impurity"
from
properties
in terms of coherence
lattice
transition principle,
far
it is very theories and
between
we provide
acco~mts
fermions
Kondo
subject
relevant,
diffused
electrons, this picture reduces to that of a Kondo singlet involving (~/a) atomuic sites 1
In this paper, model I
fermions
become
The binding
637
c
energy
Kelvin.
of a Kondo
of
impurity
("Giant a the
In
quantities non-linear
Kondo
characteristic size
of
the
A P H E N O M E N O L O G I C A L PHASE TRANSITION M O D E L FOR HEAVY P A R T I C L E S
638 T
= Tc(f)
c
have
O n the other hand, proportional
to
dimensionality where d =
the
i)
substituting
(i) the n u m b e r of such GKI b e i n g
f-d
(where
of a GKI
coherence
the
(4)
:
d is the E u c l i d i a n
F = f-D = ruD ~(TcT-I )
takes
place
a l o n g a line,
a
(5)
w h e r e T c = l ( ~ ) "dz - IA -v/~ and
I =
D----d ' ~ d z
impurity 2 of
We
size
is the
f.
identical
shall
same
as
r a p i d l y above, written
now
in
The to
scaling form function
that
of
admit
(6)
the phase
everything
scaling
function
of
the
(Tc/T).
need
F(TcT'I , hT °~°)
T vD
=
:
(7)
is
i.e. the free energy c a n be also we
a
In the p r e s e n c e of a m a g n e t i c f i e l d h
2
transition described
which
is
r e d u c e d K o n d o lattice t e m p e r a t u r e
F that
dimensionality,
introduce
i
f is
ref.
F = f-D, w h e r e f = T "u ~(AT "¢) (D is a n
effective
-
(2)
= Tf(Tc(f)T'1)
necessarily
a
above
~ must as
g i v e n for a "true" impurity.
is
that
c o n s e q u e n c e the free e n e r g y c a n b e w r i t t e n
:
Fi(f)
an
the
find
and
F(x )
not
we given
; in the s i m p l e s t case
F - ~-d Fi(f )
of
(2)
form
the free e n e r g y of the a s s e m b l y o f GKI
w i l l be
where
in
scaling
Vol. 71, No. 8
and therefore all the t h e r m o d y n a m i c a l v a r i a b l e s such as
the susceptibility,
etc.., can be d e d u c e d
to
the specific heat,
:
X = T -7 X(TcT-*),
C = T x'= C(TcT'X)
(8)
to pay the coast of our assumption,
scaling
function
and
A
a
characteristic
etc...
energy). Different As
for
critical flipping
the
slowing time ~
of the impurity c
= To
Here the
(~)dz
well-known down,
the
phenomenon
should increase w i t h
c
of
characteristic the size
:
limits
asymptotic f(x) = when
I +
T
~
x
TO
is
X
a
reciprocal
flipping
time
exchange
of
energy
(r 0 - h/A) and z is a dynamical exponent.
= A(~) -dz ; z > 0 a c
(4)
limits
easily,
even
field.
Since
heavy
fermions
x
<<
C/T
i.
-
In p a r t i c u l a r
T "~ f c '
T "~ c '
can
also
be
obtained very
in the p r e s e n c e of a m a g n e t i c we
are :
2
Dv
- ~
dealing with non magnetic
the o r d e r p a r a m e t e r ~ s h o u l d be
n e g a t i v e or null C o r r e l a t i v e l y the K o n d o e n e r g y is : T
for
=TcT,
(3)
characteristic the
o b t a i n e d f r o m the u s u a l -a - x for x > > I a n d
R = C/xT = T2(Du'l)etc... c
; z > 0
of
f(x)
+...
0,
Other
order
are
forms
=
- dv + i = ~ + fl - 7 + 2fl
with
(9) ~ 0, vdz = i It
is
worthwhile
noticing
that
these
exponents refer to T and T c (h - 0). N o w we can define the
same
way
as
for
an e f f e c t i v e mass,
the
flipping
time,
in by
i n t r o d u c i n g the e x p o n e n t p :
= mo (~)pD , p > 0
mc
m o is the effective by
an
isolated
extension
fK"
mass
Kondo
In
an
(i0)
of e l e c t r o n s d i f f u s e d impurity
ideally
of
rigid
spatial
picture
p
should be equal to u n i t y and in any case p > 0. Clearly
enough
our
quantity
;
propagates
it
electrons, heavy
"coherent FIGURE
I
and
particle
is
near
is
a
static
conduction
equivalent
a null
dominated the
not
with
therefore
(having
regime"
fluctuations
GKI
by
spin).
to
a
In
this
critical
spin
absolute
zero
of
Vol.
71, No. 8
temperature (i0) is :
A PHENOMENOLOGICAL
the
form
PHASE TRANSITION
of ~ to be substituted
= T -~ f(Tc T . 1) However this
regime
essentially nothing
can
also
use
when
spin
fluctuations
but
the
scale.
Kondo
(I0)
the
act
where
f
is
of assemblies
or "giant" resistivity
(a)
(~ > can
; P > 0
~K ) be
(13)
For
single
non- interacting
impurities,
the
number of particles is constant and equal to n o the number of Kondo sites ; furthermore the (12)
Note transitions
that our simple analogy with phase at zerc Kelvin indicate that T and c T K are connected to each other : T c = T K - A I. The expressions (ll) and (12) simply are the limits
near the phase
(ii)
and
well
characteristic
transition
above
time
for elastic
(12)
of
reflects
by
balistic collisions,
the
the
;
the
problem
"width
The scaling form of the for these two limits are then :
low
temperature
mK
=
regime
of
is the
affeetive
mass
(TcT-I , hT - ~ ° ) for the where
flipping
time z.
temperatures
f > fK'
and
(T ~ O) will not be time
T but by the c different site corresponds to
between This case
T < T K.
m A
(~a)-b .
f > f K ' p = Pc = ~ Since
Pc
must
decrease
GKI increases,
when
b=D(Z-p)-d
the
size
(14)
( of the
b > 0. In this case T = T . c
regime".
m c = mo T -pDv Mc
diffusions
the
at zero K e l v i n
it
temperature
simply
critical
classes
iP
m
< ~K' P = PK = ~
dominated
Tc
main
639
is
: = T-* ~ (TKT-I)
TK ;
two
of incoherent (f _< ~K ) Kondo impurities, the written in this model :
beyond
This regime
regime
For
in
(ii)
at the atomic
else
given by
one i.e.
MODEL FOR HEAVY PARTICLES
Using the forms of ~K(T) and ~(T) given above we deduce the scaling (and the low temperature limits) forms of the resistivity : Far of the critical
regime
:
(ii) PK ~ T'P PK (TKT-I)
m0 T'P
temperature mass
~(TKT-I, regime
increases
between
hT -4°)
where
when
for
~ S ~K"
the
the
PK ~ TKP
decreases
In the critical
:
For T = Te, m e = mo Tc-PDv
(15)
The effective
temperature
T K and T c. In particular
high
regime
:
Pc o~ T ub Pc (TcT-1) Pc a TUbc
and
(16)
(12) T = T K , m K = mo T K p The
other
limits
and field dependant
Well
which
are
temperature
can also be evaluated.
critical unitary
The
resistivity
impurity
is
given,
at
p - p0(l (T/TK)~) limit s . Our physical allows
an extension
in which the
the
size
of
v e r y different
low
single
Kondo
temperature,
of this Fermi liquid
o~
Kondo
a
by
limit GKI.
lattice
theory
is renormalized
to
Therefore,
the
is
approach
in
our
from a simple Fermi liquid.
number
of
heavy-particles
= lifetime
where
critical
where
the
depends
on
"~-renormalized the
temperature
the
~(x) - x -a - x -(a+2) length function
same +
asymptotic
form
... for the correlation
at Tc < T << T K and T << Tc :
p(T~T K) = p0(T K)
(I-P(~K)2+...)
(17)
= p0(T c) ( l + b ( ~ ) 2 - . . . ) c
(18)
and
and
- Zc(~) : flipping time of a GKI = time of cohereHt conduction of Kondo electrons within the heavy particle
regime limit"
Using
p(T~Tc)
where b and pd are both positive. The change of sign of the T 2 coefficient between a Fermi liquid
=
region
low
Starting from the simplest Boltzmann expression for the resistivity associated with a flow of particles p = m * /ne 2 r, we just put * m = mc(f) mass of an heavy-particle, n = (~)-d~
the
P0 ~ TVb~ (TcT-*)-
where P0 is the unitary picture for heavy fermions
unitary
~
temperature
of
above
effects are sizable, the system is in a Fermi liquid limit. This is no longer the case in the
of this particle.
near
TK
and
the
Kondo
lattice
near
T c = TK-A , is in this model simply due to the fact that in the latest the time of coherent (non dissipative) conduction within the "heavy particles" r = ~0 (~/a) Dz increases c
640
A PHENOMENOLOGICAL
dramatically well
when
Lelow
nothing spin
T K.
else
the
We
but
model
relate
quantities. to
critical
phase
write
are
the
quantum
transition
set it
this
check
of
b > 0,
(14),
a
the
moment
The
the
the T -I one
T
relative
the
effective mass w i t h temperature
Furthermore
our
which,
the correlation
in
=
0,
new
of
rate), (see
eq.
14).
always
is not
Many
our
experiments
;
the
3.
All
the
if we
From
our
This
(or holes) of
~,
origin
size the
or
electrons bounding might
of
f
b = 31
always
the number
volume =
values
of
exponent
~.
not
the
or
holes
mechanism
experiments the moment
phase
satisfied >
0.
(see
During
below
them
containning
the
scheme the
a
figure
2b)
renormalization
critical
of non correlated
volume b y the clusters)
divided
the inequality fd > (D
temperature,
moments
can be w r i t t e n
Vexcl = 1 - ~-[ D - 4 = 1 - t~ where
~ > 0, Vexcl
is an increasing
the
(a)
evaluated,
~
bounded
an
even
and
value
the following values
of
into a Kondo picture
cluster of
being
of
quantum
of
bounded
it
the
is
between
given
can give
d.
general
whatever is),
for
a pair
number
of our exponents
will be we
are
be
in which
fluctuations
any
staggered
the sample is schematically of
on the
usal
in
include
for
(in a more
to
take
at
initial
in r e l a t i o n
In
spatial
antiferromagnetic
due
determination
the
:
=included
negative
have b e e n done
might
a value picture,
into a fluctuating size
of
should therefore
does
exponents
assumed
starting
electrons
to length
dimensionality
of other contributions 4 .
now,
singlet
related
(excluded :
P0 a cb/s
effective
be
to
of
that Po a c (at least if c
of our clusters
equal
the
to I/T.
shall conclude by a d i s c u s s i o n
concept
magnetization
is
scattering
As a consequence
dimensionality existence
that
show a low
(21)
(see e.g. ref (i) and therein
large).
model
low value
A(fo/a) "2d
=
just
showing
too
the
process
in h e a v y fermions ref)
correlation
length should be limited to the
gives the residual resistivity
shows also
only
transitions
picture
diffusion
to C/T
term must
is
~
strong
a
limiting
the
because
(with
the
ratio
defects,
~D ~ c'Z/s where c is the c o n c e n t r a t i o n
defects
indicates to
into f-d boxes, each cluster of volume fD ; of
. c
A T s contribution
coupling, and
R
or pressure
presence
or
or the
value
changes
physical
the
example
(T T "2)
but proportional
v i r t u a l excitations
(d Ln mc/dT = d Ln mc/dT c = - pDu).
according
heat
for
X (TcT-=),
the
(19)
little
up
upturn,
Wilson
exchange
with
size
specific
We
only
(Tc/A)2e.
=
X0 =
constraint
i - ud + z P < I + wd therefore
R
susceptibility
Tr3/2,-
can
C/T - T "1 C
upturn
such as :
and
on
X = T-3
heat
temperature
The
we
concerning
mass-exponent
ratio
temperature
therefore
the
values
Vol. 71, No. 8
the
verifying
At
exponents.
implies
be
these
susceptibility
specific
linear
of the n o n proven
model 4.
these
now
with
and
only give some indications
values
will
exponents
relations
an a-posteri
measurable
comparison
the
Wilson
at
of exponents
many
that
by
different
of
a
other
believe
scaling
hypotheses shall
GKI
to
each
find,
experiments, proposed providing
a
provides
to We
possible
near
of
From
decreases
the
(for TK=~).
This which
that
clusters
fluctuations
zero Kelvin
temperature
recall
PHASE TRANSITION M O D E L FOR HEAVY PARTICLES
physical
clear i
and
that 3.
(b)
d
The
in relation with
in another
paper.
from the relations
l
At
(9),
:
= 0, Dv = i, 40 = i, 7 = i, dv = ~ << i = -I, Dv = I, 4o = 2, 7 = 3, d~ = ¢ << i
FIGURE 2
a
function of
A PHENOMENOLOGICAL PHASE TRANSITION MODEL FOR HEAVY PARTICLES
Vol. 71, No. 8
In the present model where ~ < O, the cluster volume fD is larger than the volume allowed by each bc,x ~d, leading to an overlap between different clusters (figure 2b), and consequently to a "cluster included volume" Vinci = I - El D-4
subjected to the destructive interference of overlapping clusters (it is clear that there is no phase coherence between different clusters).
which
dynamical
constant
;
volume of cluster cores in
correlations
the
core
f(fd-D-l)I/D.-
This
decrease
down
to
f'fcore'
which
are
size
correlation
zero
over
re]presents
essentially
is
~core
length
the distance
the
thickness
=
will
represents therefore
the ~ n increase
be
considered
can be very
as
particles
small
of
size
if ~ is large
(contrarily to the excluded volume of usual phase transitions the included volume is a decreasing function of f). In particular, we always have the inequality fcore << fK' the usual Kondo impurity spatial extension in a diluted system (without overlap). These bags of spin fluctuating coherently can be considered as "Kondo droplets" or more generally "spin fluctuating quantum droplets "I. They are a direct consequence of the negative value of the staggered magnetization exponent ~ (This point will be discussed in more details in ref 4).
6 = of a
continous transit:ion region of dynamical moments separing different clusters of coherent quantum fluctuations (dynamical domain wall characterized by a gradient of coherence of spin fluctuations). The total proportion of moments belonging to walls is ~ fD-d .
can
~core which
This volume measures the proportion of magnetic moments belonging to a given cluster and fluctuating coherently without being
Vinci represents ~ e
temperature decreases or the exchange interaction A increases (physically due to increasingly destructive interferences volumes associated with larger exchange couplings between localized sites). Clearly enough our CKI D
(22)
641
these quantum dynamical I ; this volume also fluctuating sites which with ~ i.e. when the
A C K N O ~ S
We are grateful to C.M. Varma who encouraged us to develop this model at the ICAREA conference and to C. Bastide, M. Cyrot and P. Stamp for their interest and critical remarks. More recently M. Papoular read in details our manuscript. He is gratefully acknowledged for his suggestions. We are also pleased to thank Drs J. Vannimenus and N. Ashcroft for interesting discussions.