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Competitive doping in polypyrrole
Synthetic Metals, 41-43 (1991) 295-299
295
COMPETITIVE DOPING IN POLYPYRROLE
D.J. WALTON, D.M. HADINGHAM, C.E. HALL, I.V.F. VINEY and A. CHYLA* Department of Applied Physical Sciences, Coventry Polytechnic, Priory Street, Coventry CVl 5FB, U.K.
ABSTRACT The electrooxidation
of pyrrole in electrolytes containing both perchlorate
and tetrasulphonato copper (II) phthalocyanine anions produced polypyrrole films from aqueous methanol that were TSCuPc-rich. methods gave similar results.
Potentiostatic and galvanostatic
However, a similar procedure in acetonitrile pro.
duced films that were perchlorate-rich.
Electrical conductivity of the films
mirrored composition, agreeing with the trend that perchlorate-rich films have higher conductivities than phthalocyanine-rich ones.
INTRODUCTION Polypyrrole is particularly tolerant of dopant anion [I], and electrooxidation of pyrrole in various electrolyte medium can produce free-standing polymer film containing not only simple anions such as perchlorate (CI04), tetrafluoroborate
(TFB) or p-toluene sulphonate (PTS), but also containing
relatively esoteric anionic species such as poly (styrene sulphonate) tetrasulphonato copper (II) phthalocyanine
[2] or
(TSCuPc) [3,4].
We now report the results of a study into the competitive doping of polypyrrole whereby the polymer is prepared from an electrolyte solution containing more than one dopant anion.
The anionic species chosen were perchlorate and
TSCuPc and two solvent systems: acetonitrile and aqueous methanol were employed.
EXPERIMENTAL Pyrrole (Aldrich) was freshly distilled prior to use.
Potassium perchlorate,
*Permanent address: Institute of Physical and Organic Chemistry, Technical Univer sity of Wroclaw, Wroclaw, Poland
0379-6779/91/$3.50
© Elsevier Sequoia/Printed in The Netherlands
296 tetra n-butyl ammonium perchlorate, phthalocyanine
3,4',4",4"'tetrasulphonato
tetrasodium salt and p-toluene
reagents or the best available
equivalent.
(II)
The tetra n-butyl ammonium salt of
TSCuPc was prepared by double decomposition hydrogen sulphate and the tetrasodium
copper
sulphonic acid were analar grade
between tetra n-butyl ammonium
salt of TSCuPc by mixture of the salt in
water followed by extraction with dichloromethane.
The deep blue dichloromethane
solution was dried over anhydrous magnesium sulphate and evaporated
to dryness
giving fine blue crystals. Polypyrrole
films containing C104 and TSCuPc anions were produced both galvano-
statically and potentiostatlcally
in an undivided cell using indium tin oxide
(ITO) coated glass anodes and stainless
steel or platinum cathodes.
monomer was present at 0.1M; and electrolyte
concentrations
0.02M for perchlorate
and from OM to 0.005M for TSCuPc
thereby corresponding
to a similar number of charges).
Galvanostatic
Pyrrole
varied from OM to
(which is a tetraanion,
control was maintained by a Thurlby PL 320 galvanostat and a _2 was passed for 1 hour. Electrolyte solutions at
current of density of imA cm perchlorate/sulphonate employed.
ionic ratios of 0:100, 25:75, 50:50,
Experiments were performed
perchlorate respective
and the tetrasodium
in 3:1 methanol/water
75:25 and 100:0 were using potassium
salt of TSCuPc; or in acetonitrole
using the
tetra n-butyl ammonium salts.
Potentiostatic
control was maintained by an EG&G MODEL 273 Potentiostat against
a saturated calomel reference electrode 3:1 aqueous methanol.
(SCE).
Experiments were all performed
in
A series of films was prepared at the same electrolyte
ratios as above, all at +1250 mV (vs. SCE); then a second series of films was prepared at a constant
sulphonate
to perchlorate
tials varying between +1000 and +1500 mY.
All
ionic ratio of i:i, at potenelectrolyses
were maintained
until the passage of 10 Coulombs of charge. Free-standing
films were examined
for compostion by elemental microanalysis
and energy dispersive analysis of X-rays
(EDAX).
The temperature
film conductivity was also measured over the temperature four probe
dependence
of
range 293- 77 K, by the
technique using J2E signal generator at i000 Hz [5,6].
RESULTS AND DISCUSSION Film composition
from aqueous methanol
Table i gives the anion content of polymer films obtained both galvanostatically and potentiostatically acetonitrile medium.
from aqueous methanol,
as a function of CI04/TSCuPc
Data is obtained from EDAX measurements
Table 2 gives supportive microanalytical statically-prepared analytical
films.
techniques
and galvanostatically
ratio in the preparative
from
electrolyte
of C1 and S.
data for representative
galvano-
Some discrepancy between the bulk and surface
is evident but the trend is clear.
297 TABLE 1 The atomic percentage
ratio of sulphur and chlorine determined
analysis and room temperature
conductivity
of galvanostatically
statically prepared PPy films from different Solvent, method of deposition
Film a) number
from EDAX
Film thickness, ~m
and potentio-
solvents. EDAX atomic percentage S CI
Room temp. conductivity, S/cm
Aqueous methanol, galvanostatically
i 2 3 4 5
30 30 20 52 58
12.45 35.44 63.73 70.83 69.87
83.90 45.64 6.45 3.42 -
0.72 0.56 0.35 0.07 0.05
Acetonitrile, galvanostatically
1 2 3 4 5
18 33 30 25 93
1.60 5.43 10.32 22.81 79.37
96.70 92.13 87.23 73.19 7.32
24.15 11.65 7.09 5.71 0.01
Aqueous methanol, potentiostatically at 1250 mV
i 2 3 4 5
20 27 20 28 18
4.68 61.55 66.85 67.91 79.38
92.02 18.26 16.13 13.16 3.87
0.90 0.08 0.07 0.06 0.03
Aqueous b" methanol ) potentio" ~ statically cj
1 2 3 4
15 15 20 35
65.11 64.50 66.85 68.01
17.80 17.17 16.13 13.23
0.06 0.06 0.07 0.05
a) Respective anion CI0~/SO S ratio: 1 = i00:i, 2 = 75:25, 3 = 50:50, 4 = 25:75 and 5 = i:i00. b) Constant electrolyte ionic CI04/SO S = 50:50 ratio. c) Respective deposition potentials: 1 = 1000 mV, 2 = ii00 mV, 3 = 1250 mV, 4 = 1400 mV and 5 = 1500 mV. The films obtained as expected,
from 100% solutions
but the striking
containing
feature of this compositional
of the film from the i:i CI0~/SO S anion mixture. of anions, which corresponds perchlorate
either CI04 or TSCuPc are study is the behaviour
Here, despite the equivalence
to a 4:1 molar excess of the more mobile monovalent
ion, the ensuing film is almost completely doped with TSCuPc.
This result implies that it is possible
to produce polypyrrole
films contain-
ing unusual or esoteric dopants by employing only a small amount of this species. Moreover
from EDAX data in Table i, it can be seen that only a slight trend
towards increased
sulphur occurs at higher potentials,
fluence of electrode potential upon film composition fluence of electrolyte Film composition
suggesting
that the in-
is much less than the in-
anion ratio.
from acetonitrole
The compositional
data from mixed-anion
electrolytes
is also given in Table
I, and here it can be seen that the equal CI0~/SO S system now produces that are perchlorate-rich. therefore observed.
films
An inversion of anion selectivity with solvent is
This may be connected with solubility and solvation
factors,
298 TABLE 2 The atomic percentage galvanostatically Electrolyte composition of films
ratios of the elements present in three representative
produced films.
Percentage of elements by elemental microanalysis, found (calculated) mass % C H N C1 S Cu 0
100% Pc in 49.84 3.62 13.87 aqueous (49.79)(4.6) (14.52) methanol 100% KCI0 in aqueous me thano 1
5.55 2.20 23.01 (5.54)(2.74)(22.80)
42.42 3.10 12.16 10.36 (41.33)(4.33)(12.05)(10.17)
i:I mixture of anions a)
1.91 -
50.83
3.65
13.90
Empirical ratios a)
0.19
0.11 -
-
31.86 (32.12)
4.54
2.55
24.34
The empirical formulae of these films was determined, pyrrole rings present to counterions was determined.
formulae
16Py:IPc:21H20
3Py: ICI04:3H20
so the number of poly-
since the tetrabutyl ammonium salt of TSCuPc is not greatly soluble in acetonitrile, and during electrolysis the anode is observed.
some agglomeration
However,
of strongly coloured TSCuPc at
this material washes readily from the poly-
pyrrole film and is not incorporated
as dopant.
Film conductivities Presented solvent
in Table 1 conductivities
(exemplified by 100% CI04) are higher than 3:1 methanol/water;
general Cl04-rich
films have higher conductivities
diminution of conductivity anions
of the films obtained from acetonitrile
has been previously
than TSCuPc-rich
and in
ones.
This
observed for other poly-sulphonate
[7]. (It should be noted here that passage of too-high currents
through
Cl04-rich films can produce explosive decomposition.) It is also seen that electrode potential produces
little effect upon
conductivity within the deposition potential range of +I000 to +1500 mV. However,
the anomalous conductivity
galvanostatically
from water/methanol
having almost exclusively
for the equal-ionic-ratio
film prepared
is closer to that of Cl04-rich
film despite
TSCuPc as the dopant.
CONCLUSIONS Potentiostatic
and galvanostatic
containing perchlorate tetrasulphonato polypyrrole anion,
preparations
and tetrasulphonato
phthalocyanine
anion.
copper
of polypyrrole
from mixtures
(Ii) phthalocyanine
anions in
This procedure allows the production of
containing an esoteric anion by use of only small amounts of this
the electrolyte
readily available salt.
properties
of the solution being bolstered by a more
299
In acetonitrile are obtained
the reverse behaviour
from mixed electrolyte
controlled by choice of preparation Preliminary suggests
behaviour,
distinct
dependence
of conductivity also
doping procedure offers a means to influence
and the conductivity
films
showing that selectivity may be
conditions.
studies on the temperature
that the competitive
composition
is observed and perchlorate-rich
solutions,
characteristics
of polypyrroles
the
to produce new
from the effects of anion identity normally imposed during
polymerisation.
REFERENCES 1
Handbook of Conducting
2
D.J. Walton et al, J. Chem. Soc. Chem. Commun.,
Polymers,
T.A. Skotheim,
3
R.A. Bull, F.R. Fan and A.J. Bard, J. Electrochem.
4
D.J. Walton,
C.J. Hall and A. Chyla,
5
A.R. Blythe,
Polymer Testing,
6
G. Wegner and J. Ruhe, Faraday Discuss.
7
A. Diaz, Chemica Scripta,
New York 1986.
(1985) 871
Synth. Met.,
4 (1984)
17 (1981)
Ed., M.Dekker,
Soc., 129 (1982)
195.
145.
1009.
submitted to editor.
Chem. Soc., 88 (1989) 333.
295
COMPETITIVE DOPING IN POLYPYRROLE
D.J. WALTON, D.M. HADINGHAM, C.E. HALL, I.V.F. VINEY and A. CHYLA* Department of Applied Physical Sciences, Coventry Polytechnic, Priory Street, Coventry CVl 5FB, U.K.
ABSTRACT The electrooxidation
of pyrrole in electrolytes containing both perchlorate
and tetrasulphonato copper (II) phthalocyanine anions produced polypyrrole films from aqueous methanol that were TSCuPc-rich. methods gave similar results.
Potentiostatic and galvanostatic
However, a similar procedure in acetonitrile pro.
duced films that were perchlorate-rich.
Electrical conductivity of the films
mirrored composition, agreeing with the trend that perchlorate-rich films have higher conductivities than phthalocyanine-rich ones.
INTRODUCTION Polypyrrole is particularly tolerant of dopant anion [I], and electrooxidation of pyrrole in various electrolyte medium can produce free-standing polymer film containing not only simple anions such as perchlorate (CI04), tetrafluoroborate
(TFB) or p-toluene sulphonate (PTS), but also containing
relatively esoteric anionic species such as poly (styrene sulphonate) tetrasulphonato copper (II) phthalocyanine
[2] or
(TSCuPc) [3,4].
We now report the results of a study into the competitive doping of polypyrrole whereby the polymer is prepared from an electrolyte solution containing more than one dopant anion.
The anionic species chosen were perchlorate and
TSCuPc and two solvent systems: acetonitrile and aqueous methanol were employed.
EXPERIMENTAL Pyrrole (Aldrich) was freshly distilled prior to use.
Potassium perchlorate,
*Permanent address: Institute of Physical and Organic Chemistry, Technical Univer sity of Wroclaw, Wroclaw, Poland
0379-6779/91/$3.50
© Elsevier Sequoia/Printed in The Netherlands
296 tetra n-butyl ammonium perchlorate, phthalocyanine
3,4',4",4"'tetrasulphonato
tetrasodium salt and p-toluene
reagents or the best available
equivalent.
(II)
The tetra n-butyl ammonium salt of
TSCuPc was prepared by double decomposition hydrogen sulphate and the tetrasodium
copper
sulphonic acid were analar grade
between tetra n-butyl ammonium
salt of TSCuPc by mixture of the salt in
water followed by extraction with dichloromethane.
The deep blue dichloromethane
solution was dried over anhydrous magnesium sulphate and evaporated
to dryness
giving fine blue crystals. Polypyrrole
films containing C104 and TSCuPc anions were produced both galvano-
statically and potentiostatlcally
in an undivided cell using indium tin oxide
(ITO) coated glass anodes and stainless
steel or platinum cathodes.
monomer was present at 0.1M; and electrolyte
concentrations
0.02M for perchlorate
and from OM to 0.005M for TSCuPc
thereby corresponding
to a similar number of charges).
Galvanostatic
Pyrrole
varied from OM to
(which is a tetraanion,
control was maintained by a Thurlby PL 320 galvanostat and a _2 was passed for 1 hour. Electrolyte solutions at
current of density of imA cm perchlorate/sulphonate employed.
ionic ratios of 0:100, 25:75, 50:50,
Experiments were performed
perchlorate respective
and the tetrasodium
in 3:1 methanol/water
75:25 and 100:0 were using potassium
salt of TSCuPc; or in acetonitrole
using the
tetra n-butyl ammonium salts.
Potentiostatic
control was maintained by an EG&G MODEL 273 Potentiostat against
a saturated calomel reference electrode 3:1 aqueous methanol.
(SCE).
Experiments were all performed
in
A series of films was prepared at the same electrolyte
ratios as above, all at +1250 mV (vs. SCE); then a second series of films was prepared at a constant
sulphonate
to perchlorate
tials varying between +1000 and +1500 mY.
All
ionic ratio of i:i, at potenelectrolyses
were maintained
until the passage of 10 Coulombs of charge. Free-standing
films were examined
for compostion by elemental microanalysis
and energy dispersive analysis of X-rays
(EDAX).
The temperature
film conductivity was also measured over the temperature four probe
dependence
of
range 293- 77 K, by the
technique using J2E signal generator at i000 Hz [5,6].
RESULTS AND DISCUSSION Film composition
from aqueous methanol
Table i gives the anion content of polymer films obtained both galvanostatically and potentiostatically acetonitrile medium.
from aqueous methanol,
as a function of CI04/TSCuPc
Data is obtained from EDAX measurements
Table 2 gives supportive microanalytical statically-prepared analytical
films.
techniques
and galvanostatically
ratio in the preparative
from
electrolyte
of C1 and S.
data for representative
galvano-
Some discrepancy between the bulk and surface
is evident but the trend is clear.
297 TABLE 1 The atomic percentage
ratio of sulphur and chlorine determined
analysis and room temperature
conductivity
of galvanostatically
statically prepared PPy films from different Solvent, method of deposition
Film a) number
from EDAX
Film thickness, ~m
and potentio-
solvents. EDAX atomic percentage S CI
Room temp. conductivity, S/cm
Aqueous methanol, galvanostatically
i 2 3 4 5
30 30 20 52 58
12.45 35.44 63.73 70.83 69.87
83.90 45.64 6.45 3.42 -
0.72 0.56 0.35 0.07 0.05
Acetonitrile, galvanostatically
1 2 3 4 5
18 33 30 25 93
1.60 5.43 10.32 22.81 79.37
96.70 92.13 87.23 73.19 7.32
24.15 11.65 7.09 5.71 0.01
Aqueous methanol, potentiostatically at 1250 mV
i 2 3 4 5
20 27 20 28 18
4.68 61.55 66.85 67.91 79.38
92.02 18.26 16.13 13.16 3.87
0.90 0.08 0.07 0.06 0.03
Aqueous b" methanol ) potentio" ~ statically cj
1 2 3 4
15 15 20 35
65.11 64.50 66.85 68.01
17.80 17.17 16.13 13.23
0.06 0.06 0.07 0.05
a) Respective anion CI0~/SO S ratio: 1 = i00:i, 2 = 75:25, 3 = 50:50, 4 = 25:75 and 5 = i:i00. b) Constant electrolyte ionic CI04/SO S = 50:50 ratio. c) Respective deposition potentials: 1 = 1000 mV, 2 = ii00 mV, 3 = 1250 mV, 4 = 1400 mV and 5 = 1500 mV. The films obtained as expected,
from 100% solutions
but the striking
containing
feature of this compositional
of the film from the i:i CI0~/SO S anion mixture. of anions, which corresponds perchlorate
either CI04 or TSCuPc are study is the behaviour
Here, despite the equivalence
to a 4:1 molar excess of the more mobile monovalent
ion, the ensuing film is almost completely doped with TSCuPc.
This result implies that it is possible
to produce polypyrrole
films contain-
ing unusual or esoteric dopants by employing only a small amount of this species. Moreover
from EDAX data in Table i, it can be seen that only a slight trend
towards increased
sulphur occurs at higher potentials,
fluence of electrode potential upon film composition fluence of electrolyte Film composition
suggesting
that the in-
is much less than the in-
anion ratio.
from acetonitrole
The compositional
data from mixed-anion
electrolytes
is also given in Table
I, and here it can be seen that the equal CI0~/SO S system now produces that are perchlorate-rich. therefore observed.
films
An inversion of anion selectivity with solvent is
This may be connected with solubility and solvation
factors,
298 TABLE 2 The atomic percentage galvanostatically Electrolyte composition of films
ratios of the elements present in three representative
produced films.
Percentage of elements by elemental microanalysis, found (calculated) mass % C H N C1 S Cu 0
100% Pc in 49.84 3.62 13.87 aqueous (49.79)(4.6) (14.52) methanol 100% KCI0 in aqueous me thano 1
5.55 2.20 23.01 (5.54)(2.74)(22.80)
42.42 3.10 12.16 10.36 (41.33)(4.33)(12.05)(10.17)
i:I mixture of anions a)
1.91 -
50.83
3.65
13.90
Empirical ratios a)
0.19
0.11 -
-
31.86 (32.12)
4.54
2.55
24.34
The empirical formulae of these films was determined, pyrrole rings present to counterions was determined.
formulae
16Py:IPc:21H20
3Py: ICI04:3H20
so the number of poly-
since the tetrabutyl ammonium salt of TSCuPc is not greatly soluble in acetonitrile, and during electrolysis the anode is observed.
some agglomeration
However,
of strongly coloured TSCuPc at
this material washes readily from the poly-
pyrrole film and is not incorporated
as dopant.
Film conductivities Presented solvent
in Table 1 conductivities
(exemplified by 100% CI04) are higher than 3:1 methanol/water;
general Cl04-rich
films have higher conductivities
diminution of conductivity anions
of the films obtained from acetonitrile
has been previously
than TSCuPc-rich
and in
ones.
This
observed for other poly-sulphonate
[7]. (It should be noted here that passage of too-high currents
through
Cl04-rich films can produce explosive decomposition.) It is also seen that electrode potential produces
little effect upon
conductivity within the deposition potential range of +I000 to +1500 mV. However,
the anomalous conductivity
galvanostatically
from water/methanol
having almost exclusively
for the equal-ionic-ratio
film prepared
is closer to that of Cl04-rich
film despite
TSCuPc as the dopant.
CONCLUSIONS Potentiostatic
and galvanostatic
containing perchlorate tetrasulphonato polypyrrole anion,
preparations
and tetrasulphonato
phthalocyanine
anion.
copper
of polypyrrole
from mixtures
(Ii) phthalocyanine
anions in
This procedure allows the production of
containing an esoteric anion by use of only small amounts of this
the electrolyte
readily available salt.
properties
of the solution being bolstered by a more
299
In acetonitrile are obtained
the reverse behaviour
from mixed electrolyte
controlled by choice of preparation Preliminary suggests
behaviour,
distinct
dependence
of conductivity also
doping procedure offers a means to influence
and the conductivity
films
showing that selectivity may be
conditions.
studies on the temperature
that the competitive
composition
is observed and perchlorate-rich
solutions,
characteristics
of polypyrroles
the
to produce new
from the effects of anion identity normally imposed during
polymerisation.
REFERENCES 1
Handbook of Conducting
2
D.J. Walton et al, J. Chem. Soc. Chem. Commun.,
Polymers,
T.A. Skotheim,
3
R.A. Bull, F.R. Fan and A.J. Bard, J. Electrochem.
4
D.J. Walton,
C.J. Hall and A. Chyla,
5
A.R. Blythe,
Polymer Testing,
6
G. Wegner and J. Ruhe, Faraday Discuss.
7
A. Diaz, Chemica Scripta,
New York 1986.
(1985) 871
Synth. Met.,
4 (1984)
17 (1981)
Ed., M.Dekker,
Soc., 129 (1982)
195.
145.
1009.
submitted to editor.
Chem. Soc., 88 (1989) 333.