We had previously reported on a surface analysis investigation of electrochemically synthesized, both oxidized and reduced, polypyrrole-poly-4-styrenesulfonate free-standing films (Sin et al., 2000). We apply the same techniques that we used earlier (Sin et al., 2000) to study polypyrrole-poly(vinylsulfonic acid, sodium salt) (PPy-PVS) free-standing films. Electron Spectroscopy for Chemical Analysis (ESCA) and Time of Flight Secondary Ion Mass Spectrometry (TOF-SIMS) were used in the surface morphology study of oxidized and reduced PPy-PVS composite films. ESCA spectra seem to indicate that the CO and C–OH structures reduced to C–C bonds during the reduction process and also seem to reveal interesting charge transfer behavior, namely. NH+ and N–H bonds to imine group (N=C) at reduced PPy-PVS free standing films. Furthermore, TOF-SIMS ion mapping also provided some interesting surface distribution of elements on PPy-PVS composite films. A comparison of surface conductivities between the two sides of both types of films was made,with conductivity measurements being carried out using the four-point probe technique.
1. Introduction
Polypyrrole (PPy), one of the most extensively studied conducting polymers, has been recognized for its long-term conductivity stability and ability in forming homopolymers or composites with optimal mechanical properties with conductivities up to 1000 S/cm which approach the conductivity of metals [1, 2]. PPy is used in numerous technological applications, such as in the fabrication of molecular electronic devices [3], electrodes for solid-state batteries [4], as solid electrolytes for capacitors [5], electromagnetic interference-shielding materials [6], ionsensors [7, 8], and ionexchangers for waste-water treatment [9, 10]. Gade et al. [11] reported the immobilization of glucose oxidase on a PPy-PVS composite film that was used as a biosensor to determine glucose and had characterized the composite films using electrochemical techniques, electrical conductivity measurements, UV–Vis spectroscopy, Fourier Transform IR spectroscopy, and Scanning Electron Microscopy. Gambhir et al. [12] reported the adsorption of DNA onto PPy-PVS films which were also characterized by similar studies. Because of the many potentially useful applications of PPy-PVS composite films [11, 12], it is desirable to investigate further the surface morphology, conductivity, and composition of such oxidized and reduced conducting polymer films. ESCA has long been an important analytical tool for semiquantitative elemental analysis of surfaces (10–20 nm depth) of polypyrrole composite materials [1, 13–19]. Ge et al. [13], using X-ray photoelectron spectroscopy, had observed that the original positive charges on polypyrrole (–NH+–) were mostly replaced by –NH– and –CH– and were oxidized to –COH– and subsequently changed into –C=O during overoxidation.
We had investigated the surface features of PPy-PSS in our earlier work [1]. The present investigation focused on free-standing PPy-PVS films which were peeled off from titanium plate electrodes after electrosynthesis at oxidizing and reducing potentials. The morphology of the two surfaces of free-standing PPy-PVS films was studied and their surface features were characterised using electrical conductivity measurements, ESCA, and TOF-SIMS. PPy-PVS films were electrochemically synthesized with various concentrations of poly(vinylsulfonic acid, sodium salt) and pyrrole in aqueous solutions and the surface conductivities of both sides of each film were determined using the four-point probe technique. ESCA was used to study the charge transfer behaviour of the deprotonated pyrrolium nitrogen (NH+) and N–H bonds with that of the imine nitrogen (N=C), and the CO with C–OH structures to C–C bonds at oxidizing and reducing potentials of polypyrrole composite films used. TOF-SIMS images would reveal interesting structural features of surface morphology of the PPy-PVS films prepared in this work.
2. Experimental2.1. Chemicals and Reagents
Titanium foil (0.127 mm thick, 99.7% pure, from Aldrich Chemical Co. Inc.) was used as anode material. Platinised titanium gauze from Morgett Electrochemicals Ltd., UK was used as counter-electrode material. Pyrrole (Fluka Chemical) was distilled under reduced pressure and stored under oxygen-free nitrogen in darkened flasks. All the films listed in Table 1 were prepared from analytical grade poly(vinylsulfonic acid, sodium salt) from Aldrich Chemical Co. Inc. and used without further purification. Doublydistilled water was used for solution preparations.
The surface conductivity at the electrolyte and electrode sides versus different concentrations of pyrrole on the oxidised PPy-PVS composite films.
Concentration of pyrrole (mole kg-1)
Thickness (mm)
Surface conductivity (Scm-1)
Percentage of difference (%)
Electrolyte side
Electrolyte side
0.1
0.0311
0.01838±0.001
0.01838±0.001
0.19
0.2
0.0208
0.02380±0.002
0.02380±0.002
0.42
0.3
0.0210
0.04110±0.002
0.04110±0.002
0.24
0.4
0.0219
0.05460±0.002
0.05460±0.002
0.18
0.5
0.0225
0.06214±0.001
0.06214±0.001
0.16
2.2. Instruments
The electropolymerization cell consisted simply of a flag-shaped Ti anode plate and two rectangular pieces of platinised Ti gauze cathodes, placed on either sides of the anode plate, in a 150cm3 beaker containing the forming solution. An Ag/AgCl/KCl (aqueous, saturated)/ceramic junction electrode was used as reference electrode and magnetic stirring was used. An EG&G PAR Model 363 Potentiostat-Galvanostat was used for current or potential control, together with a Keithley Model 197 Digital Multimeter.
ESCA data were obtained using a VG Microtech Spectrometer with a dual anode (Mg/Al) X-ray source and Clam 2/4 V triple channeltron analyser (Fissons Instruments). VG Microtech’s VGX 900I data system was used for data acquisition and analysis. Mg Kα radiation at 1253.6 eV was used for all samples studied. TOF-SIMS spectra, secondary electron (SE) images, and secondary ion (SI) maps were obtained using a Cameca TOF-SIMS IV system with a Ga primary ion gun. Raster area for ionmapping was 500 μm × 500 μm and raster resolution was at 128 pixel ×128 pixel which yielded a lateral resolution of about 4 μm. UHV in both the XPS and TOF-SIMS sample chambers, which were interconnected with an interlocking gate, was maintained at 10-8–10-9 mBar. ESCA preceded TOF-SIMS analysis for every sample.
2.3. Electrochemical Preparation and Surface Characterizations of PPY-PVS Composite Films
PPy-PVS composite films were prepared from various 0.1 mol kg-1 poly(vinylsulfonic acid, sodium salt) aqueous solutions containing 0.1 to 0.5 mol kg-1 of pyrrole monomer. Each film was electrochemically deposited on a titanium anode plate at a constant current of 50 mA cm-2 and recorded in range of 1.4–2.3 V (ref. Ag/AgCl) potential for 30 minutes. A constant potential of −1.0 V (ref. Ag/AgCl) was applied for a further 30 minutes to reduce certain films in the same forming solution immediately after film formation. All oxidized and reduced films were washed several times with d-d water, peeled off from the Ti substrate, and washed thoroughly again before leaving to dry overnight in a clean oven set at 50°C, after which they were stored in vacuum desiccators. The four-point probe technique [20] was used for surface conductivity determinations, averaged over 4–6 different positions on each surface. The 4-point probe was constructed [9] from an eight-pin I.C. socket with uniform gold-plated pins, and four equally spaced pins were connected to the galvanostat and the digital multimeter in the required manner [20]. Film thickness was measured using a Mitutoyo micrometer, with a precision of ±1 nm. Free standing oxidized and reduced films formed from 0.1 mol kg-1 pyrrole and 0.1 mol kg-1 poly(vinylsulfonic acid, sodium salt) solutions were further characterized using the ESCA and TOF-SIMS techniques.
3. Results and Discussion
Table 1 shows the results of 4-point probe data for surface conductivities of both sides of oxidized PPy-PVS films, their thicknesses, and the variation of the concentration of pyrrole (from 0.1 mole kg-1 to 0.5 mole kg-1) with 0.1 mol kg-1of PVS. The surface conductivities, as measured using the 4-point probe technique mentioned, for the electrolyte and electrode sides of each film were not significantly different between their surfaces. Surface conductivity increased with increase in pyrrole (PPy) concentration in the forming solution, as shown in Table 1. The increase in PPy concentration will increase the formation of more conjugated polypyrrole chains, which in turn increase the electrical conductivity of the polymer film. Therefore, the conjugated system was the main factor in determining conductivity of the polymer film in this case. However, the films produced using 0.1 mol kg-1 of pyrrole were thicker than those films, with increase in concentration of pyrrole (from 0.2 mole kg-1 to 0.5 mole kg-1), as shown in Table 1. It shows that morphology of 0.1 mol kg-1 of PPy-PVS free standing film is more stable and flexible as compared to those films with increase in concentration of pyrrole (that are more brittle). As the good conductivity was observed with the increase in concentration of pyrrole for this polymer films, the authors urge that further investigation should be made to resolve its inadequacy when applied to study such polymers.
Furthermore, we studied 0.1 mole kg-1 of pyrrole in oxidized and reduced PPy-PVS free standing films using ESCA. The ESCA wide scans on electrolyte (side facing solution) and electrode (side facing metal) of PPy-PVS oxidised and reduced films are show in Figure 1. It was observed that the S2P core-level signal (~163 eV) [21] was decreased at the electrode side compared to the electrolyte side of PPy-PVS oxidised film. Obviously, the N1S core-level signal (~399 eV) was higher at the electrolyte compared to the electrode side of PPy-PVS reduced film and thus explained by following TOF-SIMS technique (Figures 5(c) and 5(d)). The S2P signal almost disappeared at the electrode side but it was found in the electrolyte side of PPy-PVS reduced film as shown in Figures 1(c) and 1(d). The final noteworthy features of ESCA wide scans are the Auger NaKLL core-level signal about 264 eV only found in electrolyte and electrode sides of the reduced PPy-PVS film. The auger NaKLL couldnot found in oxidised PPy-PVS film.
The ESCA wide energy scans on (a) electrolyte (b) electrode sides of PPy-PVS oxidised film and (c) electrolyte (d) electrode sides of PPy-PVS reduced film.
The wide scan for PPy-PVS oxidised film at the electrolyte side
The wide scan for Ppy-PVS oxidised film at the electrode side
The wide scan for PPy-PVS reduced film at the electrolyte side
The wide scan for PPy-PVS reduced film at the electrode side
Figures 2(a) to 2(d) indicated the C (1s) spectra obtained using ESCA, the four components are respectively attributed to the neutral carbons (~284.5 eV), C–OH or CN structures (~286 eV), CO structures (~287.7 eV), and COOH structures (~288.9 eV) [13, 18, 21, 22]. Table 2 summarised the results of the percentage of different types of carbon using the equation arisen in our earlier paper [1] that is used in present studies on PPy-PVS films. It was shown that the CO structures were slightly higher at the electrode (9.8%) compared to the electrolyte (8.0%) sides of the oxidised PPy-PVS free standing films. However, the ( C–OH) structures are slightly lower at the electrode (19.1%) compared to the electrolyte (19.7%) sides of the oxidised PPy-PVS films. The slight percentage difference between the electrolyte and electrode of oxidised PPy-PVS is probably due to the more positive charges received at electrode compared to electrolyte sides during electropolymerization process. These results are in conformity with the results arised by Ge et al. [13]. They reported that carbons are oxidized into C–OH and subsequently changed into C=O during overoxidation (>0.9 V versus Ag/AgCl) [13]. However, after applying the reduction potential (−1.0 V), the percentages of CO structures were slightly lower at the electrode (9.1%) and electrolyte (7.8%) sides of the reduced PPy-PVS film compared to oxidised PPy/PVS film. The C–OH structures are slightly lower at the electrode (15.7%) and electrolyte (19.5%) sides of the reduced PPy-PVS film compared to oxidised PPy-PVS film. It was found that the percentages of C–C bonds are increased (from 72.3% to 72.7% at electrolyte and 71.0% to 75.2% at electrode) when the reduction potential is applied. It can be concluded that C–C bonds oxidised to CO and C–OH structures during overoxidation (1.6–2.3 V). Consequently, the CO and C–OH structures slightly reduced to C–C bonds during reduction process.
Percentage of the various binding energies of elemental composite (C–C, C=N, CO, and COOH) for PPy-PVS oxidised and reduced films of the film surfaces calculated from ESCA data, using values of atomic sensitivity factors (relative to C 1s), σi [21].
PPy/PVS film
% (Binding energy (eV))
C–C
C–OH/C=N
CO
COOH
Oxidised
(a) Electrolyte side
72.3 (284.6)
19.7 (286.2)
8.0 (287.8)
3.8 (289.1)
(b) Electrode side
71.0 (284.8)
19.1 (286.2)
9.8 (287.6)
6.3 (289.0)
Reduced
(a) Electrolyte side
72.7 (285.3)
19.5 (286.5)
7.8 (287.9)
6.2 (289.2)
(b) Electrode side
75.2 (285.1)
15.7 (286.3)
9.1 (287.6)
7.1 (289.0)
C 1s core-level spectra’s (a) electrolyte (b) electrode sides of PPy-PVS oxidised film and (c) electrolyte (d) Electrode sides of PPy-PVS reduced film.
Figures 3(a) and 3(b) show the respective N 1s core-level spectra for PPy-PVS oxidised film and Figures 3(c) and 3(d) observe N 1s spectra for PPy-PVS reduced films. Figures 3(a) to 3(c) of the peaks are fitted with five respective components that are attributable to the imine N=C group(~398 eV), the N–H bond in pyrrole repeated unit (~400 eV), the positively charged nitrogen (NH+) (~401 eV), and the two high oxidation states of nitrogen (≥402 eV) in doped polypyrrole [21]. However in part (d) of Figure 3, the peaks are shown in imine group (N=C), N–H bond, NH+, and one of high oxidation states of nitrogen. We summarised the results of Figure 3 of N 1s peak of PPy-PVS oxidised and reduced films in Table 3. Table 3 shows that the amount of N–H bonds decreased significantly (from 67.3% to 59.5%) at the electrolyte side of PPy-PVS film after reduction potential was applied. After reduction process, the imine group (N=C) was increased (7.6% to 16.3% at electrolyte side and 6.7% to 17.6% at electrode side) while NH+ decreased (25.1% to 24.2% at electrolyte side and 26.6% to 14.5% at electrode side) for reduced film. Ge et al. [13] presented the replacement of some NH+ centres of PPY by N–H during overoxidation state. However, we found that the NH+ and N–H (at electrolyte side) bonds are reduced to imine group (N=C) during reduction process.
Percentage of the various binding energies of elemental composite (N=C, NH, and NH+) for PPy-PVS oxidised and reduced films of the film surfaces calculated from ESCA data, using values of atomic sensitivity factors (relative to C 1s), σi [21].
% (Binding energy (eV))
PPy/PVS film
N=C
NH
NH+
Oxidised
(a) Electrolyte side
7.6 (398.1)
67.3 (399.6)
25.1 (400.8)
(b) Electrode side
6.7 (398.2)
66.7 (399.7)
26.6 (400.8)
Reduced
(a) Electrolyte side
16.3 (398.2)
59.5 (400.1)
24.2 (401.1)
(b) Electrode side
17.8 (398.2)
67.7 (400.1)
14.5 (400.8)
N 1s core-level spectra’s (a) electrolyte (b) electrode sides of PPy-PVS oxidised film and (c) electrolyte (d) electrode sides of PPy-PVS reduced film.
Furthermore, the secondary electron images on the surface of PPy-PVS oxidised and reduced films derived from TOF-SIMS technique are shown in Figures 4 and 5. It was shown that the surface morphology at the electrode of the PPy-PVS oxidised film (Figure 4(b)) was more uniform surface than the electrolyte side (Figure 4(a)). In reduced PPy-PVS film (Figure 4(c)), a rough surface was observed at the electrolyte side. This indicated that the reorganization process occurred during the reduction process. Figure 4(d) shows the two holes observed at surface of PPy-PVS reduced electrode side, which is due to measurement of four-point probe. Figure 5(a) presented the TOF-SIMS ion distribution maps for various selected species (e.g., H, C, NH, O, OH, C2, CN, and S) at the electrolyte side of PPy-PVS oxidised film. The brightest and lightest colour intensity corresponds to the highest surface concentration of ions on the surface. It was found that the intensity of the CN and C2 elements was higher than that of other elements (e.g., S or O) at electrode side and greater than that at electrolyte side as shown in Figures 5(a) and 5(b). This indicated that the amounts of polypyrrole were greater at the electrode side, giving a uniform surface of oxidised PPy-PVS film (Figure 4(b)). Consequently, the distribution of the elements CN and S appeared to be the same at the electrolyte side of the reduced PPy-PVS film (Figure 5(c)). However, the intensity of the CN element was substantially higher than the intensity of S at the electrode side of the PPy-PVS reduced film (Figure 5(d)), leading to the conclusion that PVS anions were more in the electrolyte side surface than the electrode side surface, giving a rough surface of reduced PPy-PVS film (Figure 4(c)). Possible explanation for the presence of trace amounts of CN and S is that molecules pyrrole has formed polypyrrole film at electrode side during oxidation process, but the negative charged PVS- has trapped PPy film, were not completely balanced only by the positive charged centres of PPy as reported in our previous studies [1]. The Na and K were more evenly distributed than O, OH, C2, CN, and S as shown in Figure 5(c). The incorporation of Na (from the PVS solution) and K (from the KCl of Ag/AgCl reference electrode) was balanced by the immobilised charges of the reduced PPy/PVS film. Similar appearance was also shown in electrode side of the PPy/PVS reduced film (Figure 5(d)) and thus explained by previously ESCA wide scan (Figure 1).
Secondary electron image of the surface (a) electrolyte (b) electrode sides of PPy-PVS oxidised film and (c) electrolyte (d) electrode sides of PPy-PVS reduced film.
TOF-SIMS SI maps showing distribution of (a) H, C, NH, O, OH, C2, CN, and S on the surface facing electrolyte of oxidized PPy-PVS film, (b) H, C, NH, O, C2, CN, NO, and S on the surface facing electrode of oxidized PPy-PVS film, and (c and d) O, OH, C2, CN, S, Na, and K on the surface facing electrolyte and electrode of reduced PPy-PVS film, for a 500×500μm2 spot.
4. Conclusions
The surface conductivities of the PPy/PVS films were in the range from 0.018 to 0.062 S/cm. The variation was due to the variation in concentration of pyrrole used (in the range 0.1 to 0.5 mole kg-1). From the results obtained, it can be concluded that the electrical conductivity of the polymer film was largely dependent on the conjugated polypyrrole chains. It was shown that there is no significant difference in surface conductivities between the electrolyte sides and the electrode sides. ESCA spectra revealed the slight changes of CO and C–OH structures to C–C bonds during reduction process. The ESCA results also show the charge transfer behavior of the deprotonation of pyrrolium nitrogen (NH+) and N–H bonds to imine group (N=C) at reduced PPy-PVS free standing film. It was found from secondary ion mapping that there were more PVS anions on the electrolyte side of the reduced PPy-PVS film that give a rough surface at reduced film. However, the more CN and C2 elements (polypyrrole chain) were attributed the fine the surface of oxidised PPy-PVS film. The insertion of monovalent cations (Na or K) into the PPy-PVS film was found in reduced PPy-PVS film.
Acknowledgments
The authors would like to thank the University of Malaya for financial support and Mr. L.H. Soo of AMCAL for technical assistance. An IRPA Grant from the Malaysian Government is gratefully acknowledged.
SinS.-L.TeoL.-L.TanK.-S.ChanC.-Y.ESCA and TOF-SIMS study on oxidised and reduced polypyrrole-poly(4-styrenesulfonate) free-standing films synthesized on Ti electrodes200021068569110.1016/S1388-2481(00)00090-4GadeV. K.ShiraleD. J.GaikwadP. D.Synthesis and characterization of Ppy-PVS, P(NMP)-PVS and their co-polymer Ppy-P(NMP)-PVS films by galvanostatic method20072270277ChaoS.WrightonM. S.Solid-state microelectrochemistry: electrical characteristics of a solid-state microelectrochemical transistor based on poly(3-methylthiophene)19871097219721992-s2.0-0000336066ShackletteL. W.ChanceR. R.IvoryD. M.MillerG. G.BaughmanR. H.Electrical and optical properties of highly conducting charge-transfer complexes of poly(p-phenylene)1980133073202-s2.0-49149144544KringsL. H. M.HavingaE. E.DonkersJ. J. T. M.VorkF. T. A.The application of polypyrrole as counterelectrode in electrolytic capacitors1993541–34534602-s2.0-0027558543KuhnH. H.GregoryR. V.KimbrellW. C.Conductive textile composites3Proceedings of the 3rd International SAMPE Electronics Conference: Electronic Materials and ProcessesJune 1989Los Angeles, Calif, USA570577ImisidesM. D.JohnR.ReileyP. J.WallaceG. G.The use of electropolymerization to produce new sensing surfaces: a review emphasizing electrode position of heteroaromatic compounds199139879889LindforsT.BobackaJ.LewenstamA.IvaskaA.Study on soluble polypyrrole as a component in all-solid-state ion-sensors19984323350335092-s2.0-0029990989LianT. L.1999Kuala Lumpur, MalaysiaUniversity of MalayaShimidzuT.OhtaniA.HondaK.Charge-controllable poly pyrrole/poly electrolyte composite membranes—part III: electrochemical deionization system constructed by anion-exchangeable and cation-exchangeable polypyrrole electrodes1988251232333710.1016/0022-0728(88)85193-32-s2.0-0024087437GadeV. K.ShiraleD. J.GaikwadP. D.Immobilization of GOD on electrochemically synthesized Ppy-PVS composite film by cross-linking via glutaraldehyde for determination of glucose20066612142014262-s2.0-003593531010.1016/j.reactfunctpolym.2006.04.005GambhirA.GerardM.JainS. K.MalhotraB. D.Characterization of DNA immobilized on electrochemically prepared conducting polypyrrole-polyvinyl sulfonate films2001961–33033112-s2.0-003109514410.1385/ABAB:96:1-3:303GeH.QiG.KangE.-T.NeohK. G.Study of overoxidized polypyrrole using X-ray photoelectron spectroscopy19943535045082-s2.0-0000079724KangE. T.NeohK. G.OngY. K.TanK. L.TanB. T. G.X-ray photoelectron spectroscopy studies of deprotonated polypyrrole and its complexes1991328135413602-s2.0-0025751196PflugerP.StreetG. B.Chemical, electronic, and structural properties of conducting heterocyclic polymers: a view by XPS19848015445532-s2.0-2842538157KangE. T.NeohK. G.TanK. L.Conductive polymers: spectroscopy and physical properties19973ChichesterWileySkotheimT. A.FloritM. I.MeloA.O'GradyW. E.Ultrahigh-vacuum in situ electrochemistry with solid polymer electrolyte and X-ray photoelectron spectroscopy studies of polypyrrole1984308484648492-s2.0-000127883610.1103/PhysRevB.30.4846PerruchotC.ChehimiM. M.DelamarM.LascellesS. F.ArmesS. P.Surface characterization of polypyrrole-coated polystyrene latex by X-ray photoelectron spectroscopy1996121332453251DaviesM. C.LynnR. A. P.DavisS. S.The surface chemical analysis of a series of persulfate-initiated charge-stabilized poly(butyl methacrylate) latices using XPS and static SIMS199315612292392-s2.0-000006625010.1006/jcis.1993.1103SmitsF. M.Measurement of Sheet Resistivities with the Four-Point Probe195837711RiggsW. M.ParkerM. J.CzandernaA. W.1975chapter 4Amsterdam, The NetherlandsElsevierJosepM. R.AmadouD.JosepM. T.BloorD.Chemical structure of polypyrrole: X-ray photoelectron spectroscopy of polypyrrole with 5-yliden-3-pyrrolin-2-one end groups1991324728732