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High-θ polyacetylene: DC conductivity between 14 mK and 300 K
Sy~ztheticMetals. 28 (1989) D11 D18
HIGH-~ POLYACETYLENE:
TH. SCHIMMEL,
I311
DC C O N D U C T I V I T Y BETWEEN 14 mK AND 300 K
G. DENNINGER,
W.RIESS,
J . V O I T and M . S C H W O E R E R
P h y s i k a l i s c h e s I n s t i t u t and BIMF, U n i v e r s i t ~ t Bayreuth,
D-8580 Bayreuth, W . - G e r m a n y
W. S C H O E P E U n i v e r s i t a t Regensburg,
W.-Germany
H. N A A R M A N N BASF Ludwigshafen,
W.-Germany
ABSTRACT Highly stretch-oriented polyacetylene vities
a of
typically
20
000
-
(6.5:1)
000
room tempe-
14 mK,
~ d e c r e a s e s m o n o t o n i c a l l y by about a factor of 5 for fresh
samples
is
within
a
400
fitted
SHENG
formula
model
On
dicular
to
(a~)
the the
conductivities stretching
anisotropy A=~i/a~
mechanism
temperature
the
of
by
the
phenomenological
measurements
dent
mK
Between
at
when highly
Above
iodine.
y i e l d s conducti-
~-icm-i
rature
samples.
d o p e d with
i00
for both,
cally changes a(T)
~!
axis
of about and
~.
T = 300 K and T =
dependence and
can
be
fresh
samples,
parallel
(~i)
show
for
interpreted MONTGOMERY and
a temperature
25 i n d i c a t i n g Deliberate
perpenindepen-
a common
oxygen
fresh
limiting
ageing
drasti-
and results in a t e m p e r a t u r e d e p e n d e n c e of A.
INTRODUCTION Very lene
recently,
with
interest
300 K of fresh the
data,
[4].
however,
showed
an
well
[1-4].
of h i g h l y
above A
20
study
almost
models A
good
is
the
are fit
to
SHENG
temperature
A=al/~ , indicating
not
a common
able the
to
Q - i c m -I
has
between
iodine
showed the
precision
(equ.
independent
polyacety-
a(T)
explain
high
formula
conducting
000 of
samples h i g h l y doped w i t h
standard
dependence
synthesis
conductivities
considerable
of
the
i).
K
and
that most
temperature experimental
Fresh
conductivity
limiting mechanism
aroused 3
samples
anisotropy
for both,
a! and
a~ [4]. The e x p e r i m e n t s f o l l o w i n g questions: 0379-6779/89/$3.50
presented does the
below SHENG
are d i r e c t e d towards the formula d e s c r i b e ~(T) at
© Elsevier Sequoia/Printed in The Netherlands
DI2 temperatures
below
3
K?
Can
we
fit
to
data
correlation
between
the
samples
its
temperature
effect
and
from
the
microscopic
room
of a g e i n g
extract the
a
consistent
SHENG
temperature
formula?
dependence
value?
on the c o n d u c t i v i t y
And
of
a
finally:
anisotropy
set
Is
of
there of
a
fresh
what
is the
A?
EXPERIMENTAL (CH)x
was
obtained
by
the
elsewhere
[i]. We u s e d
films
propylene
as
and
ching.
The
in d r i e d films, setup
resulting for the
a
from
as
300
several
as 3 K.
50
data
The
SEM
3He/4He an
18
by
dilution Hz
the
ac
cryostat,
with
four-probe
and M O N T G O M E R Y
All e x p e r i m e n t s
EXPERIMENTAL
fresh
la
of
sample
to
2.8
a i by and
measured
[6,7],
about a
thickness.
4.2
we
K
was 3
used
measured
K,
we
a
via
performed
all
of
both,
leading
which
standard
to c o n s i s t e n t
four-probe
the ohmic
is
to about
technique.
regime.
Dependence the
of
temperature
fresh
depending a i of
20
000
decreasing
fresh
of
14 mK.
conductivity
a
fresh
at -
room i00
from
300
a I and
~-icm-l. The
K to
Fig.
sample
within
the
vary a
range
a
from
decreases
reduction
the
for
absolute
3 K varies
2 shows
decreasing
a~
The
temperature
000
sample.
is still
of
technique.
temperature.
samples
on the
dependence
dependence
via M O N T G O M E R Y
samples
between
with
cooling
The
was
sample
We u s e d
the s t a n d a r d within
obtained
a(T)
samples,
~-icm-l.
techniques
as d e t e r m i n e d
at
4,
Above
different
> 20 000
were performed
sample
monotonically of
K)
-
conductivity
method.
15
3 K, we a p p l i e d
shows
sample
values
the
the
mK
tempe-
we
is l i m i t e d
of
14
of
The
[4,5],
RESULTS
a) T e m p e r a t u r e Fig.
and
than
of a(300
Below
from
bridge
more
had v a l u e s
results.
determination range
resistance
measurements
accuracy value
Q.
single
curve
of
temperature
one
Each
relative
0.5
elsewhere
points.
factor
1.5
on the
range,
of the a b s o l u t e
low
iodine
pressed
this
; the a c c u r a c y
the
for
stret-
of
typically
described hours
on poly-
mechanical solution
mechanically of
described
grown
Within
0.01%
For
6.5-fold
3 K,
to
cycle.
technique
saturated
resistances
above
thousand
temperature
a
were
long K
by
in
contacts
contact
times
sweep
typically
in
aligned
doped
experiments
sweep
rature
were
CCl 4. P l a t i n u m
allowed
as
substrate
samples
polymerization
of i - 5 ~ m t h i c k n e s s
factor between
temperature from
monotonically
4 K to down to
DI3 14 mK by about the
total
varies
from
3.7
correlation, values
a factor
reduction
of
to
the samples ~5 "T
5.4
however,
~(300
K)
of 1.34
factor for
could and
the
in this t e m p e r a t u r e
of ~I by cooling these be
highly
observed
reduction
I
F
range.
Thus,
300 K to
14 mK
conducting between
factor,
samples.
the
No
individual
respectively,
for
examined.
'
o C~ ~
from
I
0%'
f O%
b ~3
f
O
o --2
[(CH)(J3)0.065 ]x MONTGOMERY M E T H O D
(:1 I
I
100
200
300 0
I
I
100
200
T/K
300
T/K
Fig. i: al (T) and ~ ( T ) of s t r e t c h - a l i g n e d (6.5:1) [(CH) (J3)0.065] x (one t e m p e r a t u r e cycle), a) fresh sample; b) the same sample after 02-ageing. I
1
I
O01A
'EE 8.1
~
,
01
1
T/K
390
E
7"~
,o
o
c~
".- 7.s:
I0-0385 0
//
/
55 380
o 6.1 0.014
I
I
I
1
2
3
I
-190
T/K
-060
070
i0g TI K
Fig. 2: at(T ) b e t w e e n 14 mK and 4 K in two d i f f e r e n t plots. The dotted line in a) is the SHENG fit, the dotted line in b) the fit to a power law.
DI4
TIK 100
50
10
I
I
I
i
E tO
42
I
I
o
cn o
~3a
34
30
a-el
26
oxygen ageing increasing
0.3
04
_k.....__
22
os 0.6 T-~/z./K -1/4
a ~oo
Fig. 3: ~i(T) for d i f f e r e n t stages of a g e i n g of by 1 at 02 (standard four-probe measurement), a) b) after 2 hours at 260 K, c) after a d d i t i o n a l 1 d) after a d d i t i o n a l 1 hour at 320 K and e) after hours at 320 K [4].
200
300 T/ K
the same sample fresh sample, h o u r at 260 K, additional 2
Fig. 4: T e m p e r a t u r e d e p e n d e n c e of the c o n d u c t i v i t y a n i s o t r o p y A = ~i/~ for the data of Fig. la (fresh sample, curve a) and Fig. ib (same sample after ageing, curve b).
b) A n i s o t r o p y and A g e i n g Deliberate drastic
ageing
of
the
samples
change of the t e m p e r a t u r e
with
oxygen
dependence
results
of both,
~i
in
a
and ~ ,
leading to a r e d u c t i o n of the c o n d u c t i v i t i e s m a i n l y at low temperatures.
Fig.
250 K for a
3 shows fresh
log(~l(T))
sample
a g e i n g of the same sample rature
value
conductivity nitude.
Only
(curve a)
by
3 K is d i m i n i s h e d
strongly
and
(curves b-e)
of a i is reduced at
versus
aged
T -0-25
for d i f f e r e n t
8 K
degrees
and of
[4]. W h i l e the room tempe-
less
than
by more
samples
between
a
factor
than
exhibit
an
of
i0,
the
5 orders
of mag-
almost
constant
factor of r e d u c t i o n of the c o n d u c t i v i t y on further a g e i n g d-e).
(curves
D15
For
fresh
dependence:
samples,
~i and ~
show almost
the a n i s o t r o p y A(T)
the
has v a l u e s of 20 - 26 and changes
by only about 2 - i0 % from 300 K to 3 K. Fig. the sample
of Fig.
same t e m p e r a t u r e
4a shows A(T)
la. A g e i n g the sample of Fig.
for
la for one week
at room t e m p e r a t u r e by 100% oxygen at ambient p r e s s u r e leads to a r e d u c t i o n of ~(300 K) by a factor of 6 and a change rature
dependence,
which
is
shown
in
Fig.
~(300 K)/~(3 K) = 2.8
for the fresh sample of Fig.
to
Fig.
more
than
anisotropy rature. fresh
in
increases
Its
sample,
changes
increase
increase
of
lb.
only
temperature
pronounced This
I00
During
slightly
this
by
dependence,
about
the
60
%
anisotropy
about
8%
(Fig.
While
it amounts
process,
at
as
towards
is
lb.
la,
ageing
however,
significantly
of
in the tempe-
room
tempe-
compared 4
b)
lower
perfectly
the
to
the
showing
a
temperatures.
reproduced
with
d i f f e r e n t samples.
DISCUSSION Different the
room
for
the
samples
Q - I c m -I, even
no
the
creasing not
fresh high-~
temperature with
~(300
of K).
contribute
This
scattering carbon higher
should
significantly (see
not
of
larger the
c o n s t a n t v a l u e ~o
and play
and who
that
below),
conductivities
did
indicate
could
not
that
the
HEEGER an
phonon
copper. than
the
This
(see Fig.
also
height
conductivity la).
ideal
of
in
with
at
that
indoes room
phonon
one-dimensional
value
of ~ to be
that
potential
asymptotically Thus,
i00 000
of PIETRONERO
explains the
Even
scattering
argued,
role
the
5 in
observed;
resistance
who
important
estimated
of be
decrease
sample
[9],
of
investigated.
dependence
curves
to
by a factor
been
is c o n s i s t e n t with c o n s i d e r a t i o n s
~ polymers, than
s(T)
This may
KIEVELSON
of
have
highest
significantly
[8]
differing
temperature
the
temperature. and
the
"metallic"
slope
samples
conductivity
for
barriers
approaches
i/~ o could be
kT
a
interpreted
as the r e s i s t a n c e d e t e r m i n e d by defect scattering. A good
fit of the t e m p e r a t u r e
dependence
is o b t a i n e d w i t h the SHENG formula
~(T)
= ~o" exp[- TI/(T + To) ]
Equ.
1 fits
the
experimental
in the
temperature).
fresh sample
[10,]2].
(i) data
rature range from 0.4 K to 300 K magnitude
for the
(Figs.
(i.e.
The
la,
2a)
in the
tempe-
for almost three orders of
parameters
~o,
T 1 and T o are
D16
given
in T a b l e
differ
from
for fresh which
sample
we
Fig
la,
dependence,
2
the
was
the
is
a
[4],
sample
400
mK.
For
Tloc,
aged
more
the the
than
factor
width.
is about which
Tlo c
the
shallow
3%.
for
3 K and
For
most
1.5,
K of
temperature deviations
fresh
is m u c h
of
300
sample
Severe
the
of
dependence
fit b e t w e e n
the
samples
a
of T 1 and T o
temperature
line
with
deviation
temperature
i. The v a l u e s
not
graphical
the average
below
by
sample,
recently
within
which
sample
For the
published
perfect
Fig.
to
samples.
was
arise
1 for the data of Fig.
sample
higher,
up
of to
50 K. sample
Go / Q-icm-i
II
fresh
w /
112
9.6
14.7
2180
71
113
9.7
15.8
12900
50
240
21
32.6
519
55
274
24
31.7
II
Table I: P a r a m e t e r s of equ.
The
SHENG
different
barriers
model
groups
assuming
has in
highly
1 and 2 (~E = k.Tl).
been
the
applied
past
conducting
doped
regions
barriers,
SHENG
derived
introduced amount
of
a parabolic
where
E
is
the
image
dielectric
A
describes by
potential
transfer
is caused For para-
The
applicability
of
is not quite obvious
correction, is given
by
constant
of
by
~(T)
fluctuations.
A in his theory,
force
barrier.
i.
however,
a parameter
gives
equ.
polyacetylene
It
separated
e n h a n c e d by thermal v o l t a g e
SHENG model to polyacetylene,
for the
to
[4,12-16].
of w i d t h w and height V o. The charge
by tunneling,
SHENG
~E / m e V
76
(Y..u
bolic
T1 / K
53500
~
aged
TO / K
which
the
[17]:
is a measure
and which,
for
A=0.07
l=0.795-e2/(16~coWVo) the
barrier
[12].
The
v a l u e s of w and V o r e s u l t i n g from our e x p e r i m e n t a l data of T o and T 1 (see Table theory. However, data
i),
in the
approaches temperature thermally
are
not
in a p h e n o m e n o l o g i c a l
is possible,
model:
however,
a
low
consistent
model,
independent
of the
temperature
limit
finite
value
~(T=0)
=
conductivity
A
in SHENG's
an i n t e r p r e t a t i o n of the
applicability of
equ.
i,
the
~o'exp(-Tl/To);
limit T >> To, G(T) b e c o m e s activated
with
of
the
SHENG
conductivity in
the
high
a = a o - e x p ( - T l / T ) being a
with
an
activation
energy
DI7 A E = k T I. Thus,
the SHENG
a formula w h i c h limits
and
as
correctly
which,
interpolates
formula
in
between
a tunneling
(equ.
describes
the high
accordance
these
i) may be r e g a r d e d just as
with
limits.
The
yields
the
conductivity
and
the
low t e m p e r a t u r e
experimental
interpretation width
w
of
of the
data, a(T=0)
potential
barriers:
(2)
TI/T O = v ~ m V ~ - ~ . w . 2 / h (rectangular barriers). data of Fig.
The values of bE and w r e s u l t i n g
1 are shown in Table I. Thus,
from the
reasonable microscopic
p a r a m e t e r s of the b a r r i e r s can be derived. For v e r y low t e m p e r a t u r e s temperature
dependence
the d o m i n a t i n g on
less
fitted
~(T)
=
a
+
higher
of
the
aged
temperatures
expected, and bE.
ageing
g.
in
this
see Fig.
ageing
[18],
~(T)
temperature
only
be
for T
> 50
K
(e.g.
in
Fig.
cannot range,
be but
6 = 0.0247),
2b.
can
leads to an increase
For strong
a change
(~ = 6716 Q-Icm-IK-B,
samples (e.
indicates
samples
b-T 0"5
= ~-T s,
log(~(T))~log(T)+const., ~(T)
which
m u c h steeper
C o n t r a r y to other experiments
polyacetylene
obeys a p o w e r law ~(T) i.e.
observed,
t r a n s p o r t mechanism.
conducting with
is
(T<0.4 K), a different,
fitted
to
in Fig.
equ.
ib).
1 for
As
to be
in the a v e r a g e values 3, curves d-e),
no such
of w fit
is possible.
CONCLUSIONS For fresh samples of high-~ p o l y a c e t y l e n e we c o n c l u d e from our experiments, <
300
K
regions.
that the t e m p e r a t u r e
is
determined
For
becomes
much
causing
an
T
<
Tlo c
stronger, additional
by =
dependence
barriers 400
mK,
of ~ for 400 mK < T
between the
w h i c h may be due resistivity.
highly
conducting
temperature
dependence
to l o c a l i z a t i o n For
aged
effects,
samples,
Tlo c
i n c r e a s e s w i t h i n c r e a s i n g degree of ageing.
ACKNOWLEDGEMENTS We doping
thank and
discussions. ELP
03
E.
Schliebitz
sample
preparation
This w o r k was
C214-I.
for
sample and
supported
synthesis,
E.
Dormann
J.
for
by B A S F / B M F T
Gmeiner
for
many
helpful
within
Project
DI8 REFERENCES i. H. N a a r m a n n and N. Theophilou, 2. H. Naarmann, 3. N. Basescu,
Synth. M e t a l s 17 Z.-X. Liu,
H. Naarmann,
S o l i d State Commun.
Phys.
Bunsenges.
42
65 (1988)
W. RieB, Phys.
6. H. C. Montgomery, 7. B. F. Logan,
N a t u r e 327
40
1311.
G. D e n n i n g e r and M. Schwoerer, Chem.
91
(1987)
Journal of Appl.
901.
Phys.
42
Synth. Metals 8 (1983)
225.
Synth. M e t a l s 22
E. K. Sichel and J. I. Gittleman, (1978)
(1987)
12. P. Sheng, 13. Y.-W.
Phys. Rev. B. 21
Phys.
14. A. Philipp, 4!3 (1982)
73
Phys. Rev.
2180.
Druy and A.G. MacDiarmid,
(1980) 946. Solid State Commun.
857.
16. S. Masubuchi,
Phil. Mag.
K. Mizoguchi,
Synth. M e t a l s 22
B 53
(1986)
301.
K. M i z u n o and K. Kume,
(1987) 41.
to be published.
18. G. Thummes, Proc.
(1980)
M.A.
W. M a y r and K. Seeger,
15. K. E h i n g e r and S. Roth,
17. J. Voit,
371
5712.
Park, A.J. Heeger,
J. Chem.
(1988)
Phys. Rev.
1197.
Ii. E. K. Sichel, J. I. G i t t l e m a n and P. Sheng, 18
(1971) 2971.
S. O. Rice and R. F. Wick, Journal of Appl.
9. S. K i v e l s o n and A. J. Heeger,
Lett.
403.
(1971) 2975.
8. L. Pietronero,
I0. P. Sheng,
(1987)
G. Denninger,
H. N a a r m a n n and N. Theophilou,
5. Th. Schimmel, Ber.
i.
(1987) 223.
W. RieB, J. Gmeiner,
M. Schwoerer,
(1987)
D. Moses, A. J. Heeger,
N. Theophilou,
4. Th. Schimmel,
Synth. M e t a l s 22
U. Zimmer,
F. K 6 r n e r and J. K 6 t z l e r in:
of the 18th Int. C o n f e r e n c e on Low T e m p e r a t u r e
Physics Kyoto 1987.
B.
HIGH-~ POLYACETYLENE:
TH. SCHIMMEL,
I311
DC C O N D U C T I V I T Y BETWEEN 14 mK AND 300 K
G. DENNINGER,
W.RIESS,
J . V O I T and M . S C H W O E R E R
P h y s i k a l i s c h e s I n s t i t u t and BIMF, U n i v e r s i t ~ t Bayreuth,
D-8580 Bayreuth, W . - G e r m a n y
W. S C H O E P E U n i v e r s i t a t Regensburg,
W.-Germany
H. N A A R M A N N BASF Ludwigshafen,
W.-Germany
ABSTRACT Highly stretch-oriented polyacetylene vities
a of
typically
20
000
-
(6.5:1)
000
room tempe-
14 mK,
~ d e c r e a s e s m o n o t o n i c a l l y by about a factor of 5 for fresh
samples
is
within
a
400
fitted
SHENG
formula
model
On
dicular
to
(a~)
the the
conductivities stretching
anisotropy A=~i/a~
mechanism
temperature
the
of
by
the
phenomenological
measurements
dent
mK
Between
at
when highly
Above
iodine.
y i e l d s conducti-
~-icm-i
rature
samples.
d o p e d with
i00
for both,
cally changes a(T)
~!
axis
of about and
~.
T = 300 K and T =
dependence and
can
be
fresh
samples,
parallel
(~i)
show
for
interpreted MONTGOMERY and
a temperature
25 i n d i c a t i n g Deliberate
perpenindepen-
a common
oxygen
fresh
limiting
ageing
drasti-
and results in a t e m p e r a t u r e d e p e n d e n c e of A.
INTRODUCTION Very lene
recently,
with
interest
300 K of fresh the
data,
[4].
however,
showed
an
well
[1-4].
of h i g h l y
above A
20
study
almost
models A
good
is
the
are fit
to
SHENG
temperature
A=al/~ , indicating
not
a common
able the
to
Q - i c m -I
has
between
iodine
showed the
precision
(equ.
independent
polyacety-
a(T)
explain
high
formula
conducting
000 of
samples h i g h l y doped w i t h
standard
dependence
synthesis
conductivities
considerable
of
the
i).
K
and
that most
temperature experimental
Fresh
conductivity
limiting mechanism
aroused 3
samples
anisotropy
for both,
a! and
a~ [4]. The e x p e r i m e n t s f o l l o w i n g questions: 0379-6779/89/$3.50
presented does the
below SHENG
are d i r e c t e d towards the formula d e s c r i b e ~(T) at
© Elsevier Sequoia/Printed in The Netherlands
DI2 temperatures
below
3
K?
Can
we
fit
to
data
correlation
between
the
samples
its
temperature
effect
and
from
the
microscopic
room
of a g e i n g
extract the
a
consistent
SHENG
temperature
formula?
dependence
value?
on the c o n d u c t i v i t y
And
of
a
finally:
anisotropy
set
Is
of
there of
a
fresh
what
is the
A?
EXPERIMENTAL (CH)x
was
obtained
by
the
elsewhere
[i]. We u s e d
films
propylene
as
and
ching.
The
in d r i e d films, setup
resulting for the
a
from
as
300
several
as 3 K.
50
data
The
SEM
3He/4He an
18
by
dilution Hz
the
ac
cryostat,
with
four-probe
and M O N T G O M E R Y
All e x p e r i m e n t s
EXPERIMENTAL
fresh
la
of
sample
to
2.8
a i by and
measured
[6,7],
about a
thickness.
4.2
we
K
was 3
used
measured
K,
we
a
via
performed
all
of
both,
leading
which
standard
to c o n s i s t e n t
four-probe
the ohmic
is
to about
technique.
regime.
Dependence the
of
temperature
fresh
depending a i of
20
000
decreasing
fresh
of
14 mK.
conductivity
a
fresh
at -
room i00
from
300
a I and
~-icm-l. The
K to
Fig.
sample
within
the
vary a
range
a
from
decreases
reduction
the
for
absolute
3 K varies
2 shows
decreasing
a~
The
temperature
000
sample.
is still
of
technique.
temperature.
samples
on the
dependence
dependence
via M O N T G O M E R Y
samples
between
with
cooling
The
was
sample
We u s e d
the s t a n d a r d within
obtained
a(T)
samples,
~-icm-l.
techniques
as d e t e r m i n e d
at
4,
Above
different
> 20 000
were performed
sample
monotonically of
K)
-
conductivity
method.
15
3 K, we a p p l i e d
shows
sample
values
the
the
mK
tempe-
we
is l i m i t e d
of
14
of
The
[4,5],
RESULTS
a) T e m p e r a t u r e Fig.
and
than
of a(300
Below
from
bridge
more
had v a l u e s
results.
determination range
resistance
measurements
accuracy value
Q.
single
curve
of
temperature
one
Each
relative
0.5
elsewhere
points.
factor
1.5
on the
range,
of the a b s o l u t e
low
iodine
pressed
this
; the a c c u r a c y
the
for
stret-
of
typically
described hours
on poly-
mechanical solution
mechanically of
described
grown
Within
0.01%
For
6.5-fold
3 K,
to
cycle.
technique
saturated
resistances
above
thousand
temperature
a
were
long K
by
in
contacts
contact
times
sweep
typically
in
aligned
doped
experiments
sweep
rature
were
CCl 4. P l a t i n u m
allowed
as
substrate
samples
polymerization
of i - 5 ~ m t h i c k n e s s
factor between
temperature from
monotonically
4 K to down to
DI3 14 mK by about the
total
varies
from
3.7
correlation, values
a factor
reduction
of
to
the samples ~5 "T
5.4
however,
~(300
K)
of 1.34
factor for
could and
the
in this t e m p e r a t u r e
of ~I by cooling these be
highly
observed
reduction
I
F
range.
Thus,
300 K to
14 mK
conducting between
factor,
samples.
the
No
individual
respectively,
for
examined.
'
o C~ ~
from
I
0%'
f O%
b ~3
f
O
o --2
[(CH)(J3)0.065 ]x MONTGOMERY M E T H O D
(:1 I
I
100
200
300 0
I
I
100
200
T/K
300
T/K
Fig. i: al (T) and ~ ( T ) of s t r e t c h - a l i g n e d (6.5:1) [(CH) (J3)0.065] x (one t e m p e r a t u r e cycle), a) fresh sample; b) the same sample after 02-ageing. I
1
I
O01A
'EE 8.1
~
,
01
1
T/K
390
E
7"~
,o
o
c~
".- 7.s:
I0-0385 0
//
/
55 380
o 6.1 0.014
I
I
I
1
2
3
I
-190
T/K
-060
070
i0g TI K
Fig. 2: at(T ) b e t w e e n 14 mK and 4 K in two d i f f e r e n t plots. The dotted line in a) is the SHENG fit, the dotted line in b) the fit to a power law.
DI4
TIK 100
50
10
I
I
I
i
E tO
42
I
I
o
cn o
~3a
34
30
a-el
26
oxygen ageing increasing
0.3
04
_k.....__
22
os 0.6 T-~/z./K -1/4
a ~oo
Fig. 3: ~i(T) for d i f f e r e n t stages of a g e i n g of by 1 at 02 (standard four-probe measurement), a) b) after 2 hours at 260 K, c) after a d d i t i o n a l 1 d) after a d d i t i o n a l 1 hour at 320 K and e) after hours at 320 K [4].
200
300 T/ K
the same sample fresh sample, h o u r at 260 K, additional 2
Fig. 4: T e m p e r a t u r e d e p e n d e n c e of the c o n d u c t i v i t y a n i s o t r o p y A = ~i/~ for the data of Fig. la (fresh sample, curve a) and Fig. ib (same sample after ageing, curve b).
b) A n i s o t r o p y and A g e i n g Deliberate drastic
ageing
of
the
samples
change of the t e m p e r a t u r e
with
oxygen
dependence
results
of both,
~i
in
a
and ~ ,
leading to a r e d u c t i o n of the c o n d u c t i v i t i e s m a i n l y at low temperatures.
Fig.
250 K for a
3 shows fresh
log(~l(T))
sample
a g e i n g of the same sample rature
value
conductivity nitude.
Only
(curve a)
by
3 K is d i m i n i s h e d
strongly
and
(curves b-e)
of a i is reduced at
versus
aged
T -0-25
for d i f f e r e n t
8 K
degrees
and of
[4]. W h i l e the room tempe-
less
than
by more
samples
between
a
factor
than
exhibit
an
of
i0,
the
5 orders
of mag-
almost
constant
factor of r e d u c t i o n of the c o n d u c t i v i t y on further a g e i n g d-e).
(curves
D15
For
fresh
dependence:
samples,
~i and ~
show almost
the a n i s o t r o p y A(T)
the
has v a l u e s of 20 - 26 and changes
by only about 2 - i0 % from 300 K to 3 K. Fig. the sample
of Fig.
same t e m p e r a t u r e
4a shows A(T)
la. A g e i n g the sample of Fig.
for
la for one week
at room t e m p e r a t u r e by 100% oxygen at ambient p r e s s u r e leads to a r e d u c t i o n of ~(300 K) by a factor of 6 and a change rature
dependence,
which
is
shown
in
Fig.
~(300 K)/~(3 K) = 2.8
for the fresh sample of Fig.
to
Fig.
more
than
anisotropy rature. fresh
in
increases
Its
sample,
changes
increase
increase
of
lb.
only
temperature
pronounced This
I00
During
slightly
this
by
dependence,
about
the
60
%
anisotropy
about
8%
(Fig.
While
it amounts
process,
at
as
towards
is
lb.
la,
ageing
however,
significantly
of
in the tempe-
room
tempe-
compared 4
b)
lower
perfectly
the
to
the
showing
a
temperatures.
reproduced
with
d i f f e r e n t samples.
DISCUSSION Different the
room
for
the
samples
Q - I c m -I, even
no
the
creasing not
fresh high-~
temperature with
~(300
of K).
contribute
This
scattering carbon higher
should
significantly (see
not
of
larger the
c o n s t a n t v a l u e ~o
and play
and who
that
below),
conductivities
did
indicate
could
not
that
the
HEEGER an
phonon
copper. than
the
This
(see Fig.
also
height
conductivity la).
ideal
of
in
with
at
that
indoes room
phonon
one-dimensional
value
of ~ to be
that
potential
asymptotically Thus,
i00 000
of PIETRONERO
explains the
Even
scattering
argued,
role
the
5 in
observed;
resistance
who
important
estimated
of be
decrease
sample
[9],
of
investigated.
dependence
curves
to
by a factor
been
is c o n s i s t e n t with c o n s i d e r a t i o n s
~ polymers, than
s(T)
This may
KIEVELSON
of
have
highest
significantly
[8]
differing
temperature
the
temperature. and
the
"metallic"
slope
samples
conductivity
for
barriers
approaches
i/~ o could be
kT
a
interpreted
as the r e s i s t a n c e d e t e r m i n e d by defect scattering. A good
fit of the t e m p e r a t u r e
dependence
is o b t a i n e d w i t h the SHENG formula
~(T)
= ~o" exp[- TI/(T + To) ]
Equ.
1 fits
the
experimental
in the
temperature).
fresh sample
[10,]2].
(i) data
rature range from 0.4 K to 300 K magnitude
for the
(Figs.
(i.e.
The
la,
2a)
in the
tempe-
for almost three orders of
parameters
~o,
T 1 and T o are
D16
given
in T a b l e
differ
from
for fresh which
sample
we
Fig
la,
dependence,
2
the
was
the
is
a
[4],
sample
400
mK.
For
Tloc,
aged
more
the the
than
factor
width.
is about which
Tlo c
the
shallow
3%.
for
3 K and
For
most
1.5,
K of
temperature deviations
fresh
is m u c h
of
300
sample
Severe
the
of
dependence
fit b e t w e e n
the
samples
a
of T 1 and T o
temperature
line
with
deviation
temperature
i. The v a l u e s
not
graphical
the average
below
by
sample,
recently
within
which
sample
For the
published
perfect
Fig.
to
samples.
was
arise
1 for the data of Fig.
sample
higher,
up
of to
50 K. sample
Go / Q-icm-i
II
fresh
w /
112
9.6
14.7
2180
71
113
9.7
15.8
12900
50
240
21
32.6
519
55
274
24
31.7
II
Table I: P a r a m e t e r s of equ.
The
SHENG
different
barriers
model
groups
assuming
has in
highly
1 and 2 (~E = k.Tl).
been
the
applied
past
conducting
doped
regions
barriers,
SHENG
derived
introduced amount
of
a parabolic
where
E
is
the
image
dielectric
A
describes by
potential
transfer
is caused For para-
The
applicability
of
is not quite obvious
correction, is given
by
constant
of
by
~(T)
fluctuations.
A in his theory,
force
barrier.
i.
however,
a parameter
gives
equ.
polyacetylene
It
separated
e n h a n c e d by thermal v o l t a g e
SHENG model to polyacetylene,
for the
to
[4,12-16].
of w i d t h w and height V o. The charge
by tunneling,
SHENG
~E / m e V
76
(Y..u
bolic
T1 / K
53500
~
aged
TO / K
which
the
[17]:
is a measure
and which,
for
A=0.07
l=0.795-e2/(16~coWVo) the
barrier
[12].
The
v a l u e s of w and V o r e s u l t i n g from our e x p e r i m e n t a l data of T o and T 1 (see Table theory. However, data
i),
in the
approaches temperature thermally
are
not
in a p h e n o m e n o l o g i c a l
is possible,
model:
however,
a
low
consistent
model,
independent
of the
temperature
limit
finite
value
~(T=0)
=
conductivity
A
in SHENG's
an i n t e r p r e t a t i o n of the
applicability of
equ.
i,
the
~o'exp(-Tl/To);
limit T >> To, G(T) b e c o m e s activated
with
of
the
SHENG
conductivity in
the
high
a = a o - e x p ( - T l / T ) being a
with
an
activation
energy
DI7 A E = k T I. Thus,
the SHENG
a formula w h i c h limits
and
as
correctly
which,
interpolates
formula
in
between
a tunneling
(equ.
describes
the high
accordance
these
i) may be r e g a r d e d just as
with
limits.
The
yields
the
conductivity
and
the
low t e m p e r a t u r e
experimental
interpretation width
w
of
of the
data, a(T=0)
potential
barriers:
(2)
TI/T O = v ~ m V ~ - ~ . w . 2 / h (rectangular barriers). data of Fig.
The values of bE and w r e s u l t i n g
1 are shown in Table I. Thus,
from the
reasonable microscopic
p a r a m e t e r s of the b a r r i e r s can be derived. For v e r y low t e m p e r a t u r e s temperature
dependence
the d o m i n a t i n g on
less
fitted
~(T)
=
a
+
higher
of
the
aged
temperatures
expected, and bE.
ageing
g.
in
this
see Fig.
ageing
[18],
~(T)
temperature
only
be
for T
> 50
K
(e.g.
in
Fig.
cannot range,
be but
6 = 0.0247),
2b.
can
leads to an increase
For strong
a change
(~ = 6716 Q-Icm-IK-B,
samples (e.
indicates
samples
b-T 0"5
= ~-T s,
log(~(T))~log(T)+const., ~(T)
which
m u c h steeper
C o n t r a r y to other experiments
polyacetylene
obeys a p o w e r law ~(T) i.e.
observed,
t r a n s p o r t mechanism.
conducting with
is
(T<0.4 K), a different,
fitted
to
in Fig.
equ.
ib).
1 for
As
to be
in the a v e r a g e values 3, curves d-e),
no such
of w fit
is possible.
CONCLUSIONS For fresh samples of high-~ p o l y a c e t y l e n e we c o n c l u d e from our experiments, <
300
K
regions.
that the t e m p e r a t u r e
is
determined
For
becomes
much
causing
an
T
<
Tlo c
stronger, additional
by =
dependence
barriers 400
mK,
of ~ for 400 mK < T
between the
w h i c h may be due resistivity.
highly
conducting
temperature
dependence
to l o c a l i z a t i o n For
aged
effects,
samples,
Tlo c
i n c r e a s e s w i t h i n c r e a s i n g degree of ageing.
ACKNOWLEDGEMENTS We doping
thank and
discussions. ELP
03
E.
Schliebitz
sample
preparation
This w o r k was
C214-I.
for
sample and
supported
synthesis,
E.
Dormann
J.
for
by B A S F / B M F T
Gmeiner
for
many
helpful
within
Project
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H. Naarmann,
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Phys.
Bunsenges.
42
65 (1988)
W. RieB, Phys.
6. H. C. Montgomery, 7. B. F. Logan,
N a t u r e 327
40
1311.
G. D e n n i n g e r and M. Schwoerer, Chem.
91
(1987)
Journal of Appl.
901.
Phys.
42
Synth. Metals 8 (1983)
225.
Synth. M e t a l s 22
E. K. Sichel and J. I. Gittleman, (1978)
(1987)
12. P. Sheng, 13. Y.-W.
Phys. Rev. B. 21
Phys.
14. A. Philipp, 4!3 (1982)
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Druy and A.G. MacDiarmid,
(1980) 946. Solid State Commun.
857.
16. S. Masubuchi,
Phil. Mag.
K. Mizoguchi,
Synth. M e t a l s 22
B 53
(1986)
301.
K. M i z u n o and K. Kume,
(1987) 41.
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18. G. Thummes, Proc.
(1980)
M.A.
W. M a y r and K. Seeger,
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J. Chem.
(1988)
Phys. Rev.
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I0. P. Sheng,
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G. Denninger,
H. N a a r m a n n and N. Theophilou,
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i.
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W. RieB, J. Gmeiner,
M. Schwoerer,
(1987)
D. Moses, A. J. Heeger,
N. Theophilou,
4. Th. Schimmel,
Synth. M e t a l s 22
U. Zimmer,
F. K 6 r n e r and J. K 6 t z l e r in:
of the 18th Int. C o n f e r e n c e on Low T e m p e r a t u r e
Physics Kyoto 1987.
B.