- Email: [email protected]
Photocurrent spectroscopy of conductive polymers
ELSEVIER
Synthetic
Photocurrent
Department
Metals
69 (1995) 3.53-354
Spectroscopy
of Conductive
Jukka Lukkari and Jouko Kankare of Chemistry, University of Turku, FIN-20500
Polymers
Turku, Finland
Abstract Photocurrent spectroscopy allows to obtain spectra of ultrathin conductive polymer deposits on electrode surfaces and to study the first steps of anodic electropolymerisation. With poly(3-methylthiophene), electropolymerisation takes place by deposition of solution formed oligomers but the results for poly(N-methylpyrrole) show gradual increase in conjugation length. The preparation
of thin conductive
carried out using anodic easy control of electropolymerisation,
polymer
electropolymerisation,
the the
reiative initiation
films is usually which provides
film process
thickness. determines
transmittance, and transformed proportional to quantum efficiency. No absolute quantum efficiencies were determined.
In the
quality and properties of the resulting thin film to a large extent. However, the mechanisms of film initiation and growth have received
little attention.
either the deposition
Two mechanisms of solution
formed
have been postulated, oligomers
or gradual
growth of surface-bound chains.[l] The former model is closely related to the classical concept of nucleation. The lack of data on the early stages of film formation partly stems from the experimental difficulties involved when studying ultrathin polymer deposits. The film initiation have been studied using classical
electrochemical
techniques
[2], scanning
probe
techniques [3], and ellipsometry[4]. Ellipsometry has been the only technique providing information about the chemical nature of the deposits but it requires expensive instrumentation complex model fitting. We have found that measuring photocurrent
0 PC
Figure I : The experimental photocurrent
set-up
for the measurement
of
spectra. The light source is a 450 W Xe lamp.
and the
of the deposits as a function of the excitation energy
is an excellent in situ technique for studying the early stages of the electropolymerisation reaction.[ l] The photocurrent spectrum (in quantum efficiency) is identical to the absorbance spectrum of the deposits but the sensitivity of the method enables us to record spectra of deposits monolayer.
corresponding
to less than a hypothetical
Experimental The polymerisation was carried out from acetonitrile or aqueous solutions containing the monomer (3-methylthiophene, thiophene, pyrrole, or N-methylpyrrole, all 0.1 M) and the electrolyte (usually tetrabutylammonium hexafluorophosphate TBAF, 0.2 M). The working electrode was either indium-tin oxide (ITO) or polished polycrystalline platinum disc. The details of the polymerisation procedure and the electrochemical cells have been described elsewhere.[l] Photocurrent spectra of neutral polymer deposits were recorded using the apparatus shown in Fig. I. The light chopping reference frequency was either 2.5 Hz or 0.5 Hz. The measured photocurrents were corrected for the spectrum and monochromator and cell IamP intensity
0379-6779/95/$09.50 SSDI
0
1995 Elsevier
0379-6779(94)02482-E
Science
S.A.
All rights reserved
0.00.
Figure 2 : Cyclic voltammogram (100 mV/s) and photocurrent of poly(N-methylpyrrole) on IT0 (2.0 mC/cm* using 1.0 mA/cm2 in acetonitrile/TBAF). Results and Discussion The excitation of neutral polythiophene, PolY(3methylthiophene) or poly(N-methylpyrrole) deposits on the electrode surface produces a reductive photocurrent. The photocurrents are so low that residual oxygen or water can guarantee an electron acceptor concentration high enough even in
354
dry
J. Lukkari, J. Kankare I Synthetic Metals 69 (1995) 353-354
acetonitrile
nondegenerate
solutions.[l] ground
In
state,
conductive
photoinduced
polymers
from the formation of polarons and bipolarons excitation.[5] At least with thiophene-type formation
of these charged
chain distortions
with result
ca. 3.6 eV to cu. 2.75 eV when the polymerisation charge increases from 0.025 mC/cm2 to 1 mC/cm*. The spectra display,
after the initial polymers, the
however, a sharp rise below 350 nm with an absorption edge of 3.6 eV also at higher polymerisation charges. The same kind of
phenomena
takes place within
spectral
features
are present
in the UV-vis
spectra
of thick
the time scale of energy transfer, which enables the observation of photocurrent in thin polymer deposits on metal electrodes also.
poly(N-methylpyrrole) films.[7] This shows that the chemical nature of the polymer films is not uniform, and already very small
However, contrary to thiophenes,
poly(N-methylpyrrole)
no photocurrents
were observed
with poly(N-methylpyrrole) on platinum electrodes. A good signal was obtained with the N-methyl derivative on IT0 but we were
unable
to detect
photocurrent
with
polypyrrole
conjugation
deposits
contain
species
with different
lengths.
itself,
contrary to some previous reports.[6] In general, the absolute quantum efficiencies are rather low, and electrochemically induced charges can quench photocurrents already at low doping levels (Fig. 2). In the case of 3-methylthiophene spectra
and thiophene,
photocurrent
(Fig. 3) show that on native IT0 the absorption
edge
(band gap edge) and h,, attain the values characteristic of highly conjugated films (cu. 1.95 eV and 550 nm, respectively) already in the first observed deposits (polymerisation charge cu. 0.1 mC/cmz). This indicates that the electropolymerisation takes place by deposition of long oligomers formed in the solution. The determination of the actual conjugation length of the deposits is rendered difficult by the lack of suitable reference spectra. Solidstate effects induce a bathochromic shift in the spectra of solid films, as compared to the solution spectra of corresponding oligomers. complicates
On the other hand, splitting of energy levels the use of highly ordered evaporated films of known
oligomers.
Figure 4 : Normalised photocurrent spectra of poly(Nmethylpyrrole) deposits on IT0 (prepared using 1 mA/cm*). The behaviour thiophene-type interactions
of N-metbylpyrrole
polymers. between
species have an electropolymerisation.[l]
contrasts
We have previously
the electrode
surface
with that of shown
that the
and the deposited
important role in the Strong interactions
course favour
of the
deposition of short oligomers and even with thiophenes the initial step might be a reaction with the species adsorbed on the surface. On the other hand, weak interactions
lead to the deposition
of
long oligomers. Therefore, the differences can be explained by the higher affinity of pyrrole-type oligomers toward the hydrophilic IT0 surface. References [l] J.Lukkari,
photocurrent spectra of poly(3Figure 3 : Normalised methylthiophene) deposits on IT0 (prepared using 1 n&cm*). With poly(N-methylpyrrole) on native ITO, the results imply a somewhat different mechanism (Fig. 4). Photocurrent spectra could be obtained at much lower deposition charge densities than with thiophene-type polymers. The absorption edge of these initial deposits is co. 3.6 eV, indicating a very short conjugation length. At higher charge densities a shoulder starts to form at cu. 375 nm. The absorption edge experiences a gradual shift from
M.Alanko,
V.Pitk%nen,
K.Kleemola,
J.Kankare,
J.Phys.Chem., in press; J.Kankare, V.Vuorinen, M.Alanko, J.Lukkari, J. ChemSoc., Chem. Commun. (1993) 241. [2] AR Hillman, EF Mallen, J. Electround. Chem. 220 (1987) 35 1 [3] J.Lukkari, M.Alanko, L.HeikkilZI, R.Laiho, J.Kankare, Chem. Muter. 5 (1993) 289; F.Chao, MCosta, CTian, SynthMet. 53 (1993) 127. [4] A.Hamnett, AR Hillman, J.Electrochem.Soc. 135 (1988) 25 17 [5] G. Yu, SD Phillips, H.Tomozawa, AJ Heeger, PhyxRev. B42 (1990) 3004. [6] Y.Yang, ZG Lin, SynthMet. 64 (1994) 43. [7] DL Feldheim, M. Krejcik, SM Hendrickson, CM Elliot, J.Phys.Chem.
98 (1994) 5714.
Synthetic
Photocurrent
Department
Metals
69 (1995) 3.53-354
Spectroscopy
of Conductive
Jukka Lukkari and Jouko Kankare of Chemistry, University of Turku, FIN-20500
Polymers
Turku, Finland
Abstract Photocurrent spectroscopy allows to obtain spectra of ultrathin conductive polymer deposits on electrode surfaces and to study the first steps of anodic electropolymerisation. With poly(3-methylthiophene), electropolymerisation takes place by deposition of solution formed oligomers but the results for poly(N-methylpyrrole) show gradual increase in conjugation length. The preparation
of thin conductive
carried out using anodic easy control of electropolymerisation,
polymer
electropolymerisation,
the the
reiative initiation
films is usually which provides
film process
thickness. determines
transmittance, and transformed proportional to quantum efficiency. No absolute quantum efficiencies were determined.
In the
quality and properties of the resulting thin film to a large extent. However, the mechanisms of film initiation and growth have received
little attention.
either the deposition
Two mechanisms of solution
formed
have been postulated, oligomers
or gradual
growth of surface-bound chains.[l] The former model is closely related to the classical concept of nucleation. The lack of data on the early stages of film formation partly stems from the experimental difficulties involved when studying ultrathin polymer deposits. The film initiation have been studied using classical
electrochemical
techniques
[2], scanning
probe
techniques [3], and ellipsometry[4]. Ellipsometry has been the only technique providing information about the chemical nature of the deposits but it requires expensive instrumentation complex model fitting. We have found that measuring photocurrent
0 PC
Figure I : The experimental photocurrent
set-up
for the measurement
of
spectra. The light source is a 450 W Xe lamp.
and the
of the deposits as a function of the excitation energy
is an excellent in situ technique for studying the early stages of the electropolymerisation reaction.[ l] The photocurrent spectrum (in quantum efficiency) is identical to the absorbance spectrum of the deposits but the sensitivity of the method enables us to record spectra of deposits monolayer.
corresponding
to less than a hypothetical
Experimental The polymerisation was carried out from acetonitrile or aqueous solutions containing the monomer (3-methylthiophene, thiophene, pyrrole, or N-methylpyrrole, all 0.1 M) and the electrolyte (usually tetrabutylammonium hexafluorophosphate TBAF, 0.2 M). The working electrode was either indium-tin oxide (ITO) or polished polycrystalline platinum disc. The details of the polymerisation procedure and the electrochemical cells have been described elsewhere.[l] Photocurrent spectra of neutral polymer deposits were recorded using the apparatus shown in Fig. I. The light chopping reference frequency was either 2.5 Hz or 0.5 Hz. The measured photocurrents were corrected for the spectrum and monochromator and cell IamP intensity
0379-6779/95/$09.50 SSDI
0
1995 Elsevier
0379-6779(94)02482-E
Science
S.A.
All rights reserved
0.00.
Figure 2 : Cyclic voltammogram (100 mV/s) and photocurrent of poly(N-methylpyrrole) on IT0 (2.0 mC/cm* using 1.0 mA/cm2 in acetonitrile/TBAF). Results and Discussion The excitation of neutral polythiophene, PolY(3methylthiophene) or poly(N-methylpyrrole) deposits on the electrode surface produces a reductive photocurrent. The photocurrents are so low that residual oxygen or water can guarantee an electron acceptor concentration high enough even in
354
dry
J. Lukkari, J. Kankare I Synthetic Metals 69 (1995) 353-354
acetonitrile
nondegenerate
solutions.[l] ground
In
state,
conductive
photoinduced
polymers
from the formation of polarons and bipolarons excitation.[5] At least with thiophene-type formation
of these charged
chain distortions
with result
ca. 3.6 eV to cu. 2.75 eV when the polymerisation charge increases from 0.025 mC/cm2 to 1 mC/cm*. The spectra display,
after the initial polymers, the
however, a sharp rise below 350 nm with an absorption edge of 3.6 eV also at higher polymerisation charges. The same kind of
phenomena
takes place within
spectral
features
are present
in the UV-vis
spectra
of thick
the time scale of energy transfer, which enables the observation of photocurrent in thin polymer deposits on metal electrodes also.
poly(N-methylpyrrole) films.[7] This shows that the chemical nature of the polymer films is not uniform, and already very small
However, contrary to thiophenes,
poly(N-methylpyrrole)
no photocurrents
were observed
with poly(N-methylpyrrole) on platinum electrodes. A good signal was obtained with the N-methyl derivative on IT0 but we were
unable
to detect
photocurrent
with
polypyrrole
conjugation
deposits
contain
species
with different
lengths.
itself,
contrary to some previous reports.[6] In general, the absolute quantum efficiencies are rather low, and electrochemically induced charges can quench photocurrents already at low doping levels (Fig. 2). In the case of 3-methylthiophene spectra
and thiophene,
photocurrent
(Fig. 3) show that on native IT0 the absorption
edge
(band gap edge) and h,, attain the values characteristic of highly conjugated films (cu. 1.95 eV and 550 nm, respectively) already in the first observed deposits (polymerisation charge cu. 0.1 mC/cmz). This indicates that the electropolymerisation takes place by deposition of long oligomers formed in the solution. The determination of the actual conjugation length of the deposits is rendered difficult by the lack of suitable reference spectra. Solidstate effects induce a bathochromic shift in the spectra of solid films, as compared to the solution spectra of corresponding oligomers. complicates
On the other hand, splitting of energy levels the use of highly ordered evaporated films of known
oligomers.
Figure 4 : Normalised photocurrent spectra of poly(Nmethylpyrrole) deposits on IT0 (prepared using 1 mA/cm*). The behaviour thiophene-type interactions
of N-metbylpyrrole
polymers. between
species have an electropolymerisation.[l]
contrasts
We have previously
the electrode
surface
with that of shown
that the
and the deposited
important role in the Strong interactions
course favour
of the
deposition of short oligomers and even with thiophenes the initial step might be a reaction with the species adsorbed on the surface. On the other hand, weak interactions
lead to the deposition
of
long oligomers. Therefore, the differences can be explained by the higher affinity of pyrrole-type oligomers toward the hydrophilic IT0 surface. References [l] J.Lukkari,
photocurrent spectra of poly(3Figure 3 : Normalised methylthiophene) deposits on IT0 (prepared using 1 n&cm*). With poly(N-methylpyrrole) on native ITO, the results imply a somewhat different mechanism (Fig. 4). Photocurrent spectra could be obtained at much lower deposition charge densities than with thiophene-type polymers. The absorption edge of these initial deposits is co. 3.6 eV, indicating a very short conjugation length. At higher charge densities a shoulder starts to form at cu. 375 nm. The absorption edge experiences a gradual shift from
M.Alanko,
V.Pitk%nen,
K.Kleemola,
J.Kankare,
J.Phys.Chem., in press; J.Kankare, V.Vuorinen, M.Alanko, J.Lukkari, J. ChemSoc., Chem. Commun. (1993) 241. [2] AR Hillman, EF Mallen, J. Electround. Chem. 220 (1987) 35 1 [3] J.Lukkari, M.Alanko, L.HeikkilZI, R.Laiho, J.Kankare, Chem. Muter. 5 (1993) 289; F.Chao, MCosta, CTian, SynthMet. 53 (1993) 127. [4] A.Hamnett, AR Hillman, J.Electrochem.Soc. 135 (1988) 25 17 [5] G. Yu, SD Phillips, H.Tomozawa, AJ Heeger, PhyxRev. B42 (1990) 3004. [6] Y.Yang, ZG Lin, SynthMet. 64 (1994) 43. [7] DL Feldheim, M. Krejcik, SM Hendrickson, CM Elliot, J.Phys.Chem.
98 (1994) 5714.