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Electrochemical study of electroactive poly (5-hydroxy-1,4-naphthoquinone-co-5-hydroxy-3-acetic acid-1,4-naphthoquinone) by impedance spectroscopy

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The conducting polymer poly(5-hydroxy-1,4-naphthoquinone-co-5-hydroxy-3-acetic acid-1,4- naphthoquinone) with electroactive quinone group was investigated by Electrochemical Impedance Spectroscopy (EIS) in aqueous medium. The evaluations of parameters of equivalent circuit in term of applied potential were considered. The simulated EIS data presented a good agreement with the results obtained by other electrochemical methods.

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Nội dung Text: Electrochemical study of electroactive poly (5-hydroxy-1,4-naphthoquinone-co-5-hydroxy-3-acetic acid-1,4-naphthoquinone) by impedance spectroscopy

Journal of Chemistry, Vol. 42 (4), P. 497 - 500, 2004<br /> <br /> <br /> <br /> ELECTROCHEMICAL STUDY OF CONDUCTING ELECTROACTIVE<br /> POLYMER POLY(5-HYDROXY-1,4-NAPHTHOQUINONE -co- 5-<br /> HYDROXY-3-ACETIC ACID-1,4-NAPHTHOQUINONE) BY<br /> ELECTROCHEMICAL IMPEDANCE SPECTROSCOPY<br /> Received 3rd -Sept.- 2003<br /> TRAN §AI LAM<br /> Faculty of Chemical Technology, Hanoi University of Technology<br /> <br /> SUMMARY<br /> The conducting polymer poly(5-hydroxy-1,4-naphthoquinone-co-5-hydroxy-3-acetic acid-1,4-<br /> naphthoquinone) with electroactive quinone group was investigated by Electrochemical<br /> Impedance Spectroscopy (EIS) in aqueous medium. The evaluations of parameters of equivalent<br /> circuit in term of applied potential were considered. The simulated EIS data presented a good<br /> agreement with the results obtained by other methods such as Cyclic and Differential Pulse<br /> Voltammetries.<br /> <br /> I - INTRODUCTION frequently used is Randles circuit [3].<br /> For an ECP the behavior in the high<br /> Electrochemical methods such as Cyclic<br /> frequency (HF) and in the low frequency (LF)<br /> Voltammetry (CV), Differential Pulse Voltam-<br /> regions are similar to that of simple redox<br /> metry (DPV), Square Wave Voltammetry<br /> system. However, when the frequency is<br /> (SWV), through large perturbations (by<br /> decreased to very low values (~ mHz) the<br /> imposing potential steps or potential sweeps) on<br /> diffusion will become limited in favor of a<br /> the studied system, lead the system to the state<br /> charge accumulation into the polymer. The<br /> far from equilibrium. The obtained response is<br /> impedance approaches a purely capacitive<br /> normally transient. The principle of EIS is to<br /> introduce a small perturbation by the means of response with a phase angle of /2. This<br /> sinusoidal signal of small amplitude in order to limiting capacitance CL is associated with<br /> obtain the response in quasi- stationary state. limiting resistance RL in the following equation:<br /> This method has many advantages, among them CL= d2/ 3D.RL (d - film's thickness, D - diffusion<br /> the most important one is the ability to have coefficient).<br /> precise measurements because the response may Modified Randles equivalent circuit for ECP<br /> be indefinitely steady and the ability to<br /> distinguish processes that may occur in one The model developed by Ho et al. [4] and<br /> reaction, especially when their time constants independently by Glarum [5] for thin films of<br /> are well separated [1, 2]. intercalation materials, in which lithium<br /> injection and diffusion occur, was successfully<br /> Randles equivalent circuit for electronically used to analyze the impedance response of ECP,<br /> conducting polymers (ECP) in which the doping/dedoping processes involve<br /> In general, an electrochemical cell can be injection-removal of electrons in the polymer<br /> represented in terms of an equivalent circuit. A film balanced by counter ion diffusion from/to<br /> <br /> 497<br /> electrolyte. A more advanced model for ECP NaCl; 0.0027 M KCl; 0.0081 M Na2HPO4;<br /> has been suggested by Albery [6], Mathias and 0.00147 M KH2PO4, pH 7.4) from Dulbecco.<br /> Haas [7], who considered concurrent ionic and AC impedance measurements were<br /> electronic transport in the system. One can performed in aqueous buffer PBS, using a tree-<br /> imagine the impedance as a microstructure electrode cell, with frequency response analyzer<br /> composed of pores and cavities, represented by FRA of AUTOLAB. The reference was<br /> a transmission line. saturated calomel electrode (SCE), the auxiliary<br /> In present report, we will use Vorotynsev- was Pt sheet. The working electrode was carbon<br /> Deslouis model, initially developed for the disk (Tokai), sealed in Teflon (S = 0.07 cm2).<br /> study of metal protection by ECP [8]. In our These electrodes were potentiostatically charged<br /> case we can assume Rp and the circuit can for 120 s before the impedance measurements.<br /> be shown in figure 1. The amplitude is 10 mV, the frequency is from<br /> 50 kHz to 10 mHz, 5 points of frequency per<br /> Resistance Electrolyte/Film<br /> Film decade. The data were fitted with Vorotynsev-<br /> Electrolyte Interface Deslouis model by Simplex algorithm [10].<br /> Cef Cd<br /> III - RESULTS AND DISCUSSION<br /> Re<br /> 1. EIS spectra<br /> Ref Rt ZW<br /> Typical EIS results of polymer film at<br /> different potentials, corresponding to the<br /> Figure 1: Vorotynsev-Deslouis model used in<br /> electroactive domain of quinone group (from 0<br /> this study for simulation of experimental EIS<br /> to -0.8V vs. SCE) with potential step of 0.1 V,<br /> data<br /> are presented in figure 2.<br /> In this model, Re is electrolyte resistance; The EIS spectra comprise 3 parties. A<br /> Cef and Ref are the capacity of space charge capacitive component at high frequencies<br /> between electrolyte and polymer film and the followed by poorly defined diffusion process at<br /> charge transfer resistance associated with low frequencies. At very low frequencies, a<br /> charge insertion due to doping/dedoping au deviation from straight line is observed,<br /> processes on electrolyte-film interface. Cd and possibly due to non-uniform film thickness.<br /> Rt are double layer capacity and charge transfer Representation in Bode plot (logZ-logf) clearly<br /> resistance of the polymer film. W is Warburg demonstrated 3 these domains.<br /> diffusion impedance of the polymer film with<br /> the effect of charge saturation, which strongly The values of the circuit elements in<br /> depends on the film. function of applied potentials are summarized in<br /> table 1.<br /> II - EXPERIMENT We will try to consider the variations of<br /> these parameters with applied potentials. Firstly,<br /> 5-hydroxy-1,4-naphthoquinone (JUG) from the capacitance Ce/f, corresponding to charge<br /> Fluka (98%) was used as received. 5-hydroxy- accumulation on electrolyte-film interface<br /> 3-acetic acid-1,4-naphthoquinone (JUGA) was increases with increased potentials (in oxidation<br /> synthesized in one step from JUG and cycle) (Fig. 3a). This tendency can be explained<br /> thioglycolic acid (from Acros). A detailed if the decrease in diffusion layer formed<br /> procedure has been described elsewhere [9]. between the counterions and oxidized polymer<br /> Poly (JUG-co-JUGA) was electro-synthesized film is taken into account. Secondly, double<br /> by CV, on Autolab, model PGSTAT 30 (50 layer capacitance Cd of the polymer film goes<br /> cycles, potential domain 0.40 - 1.05 V vs.SCE, through a maximum around –0.4 V, which is<br /> scan rate 50 mV.s-1). the potential, corresponding to the current peak,<br /> Aqueous solution buffer is PBS (0.137 M observed in CV’s method (Fig. 3b). Thirdly, we<br /> <br /> 498<br /> 1.1 Hz 220<br /> 120<br /> 1.1 Hz<br /> 200<br /> 1.1 Hz 1.1 Hz<br /> 100 180<br /> <br /> 160 1.1 Hz<br /> 80 1.1 Hz 140<br /> 1.1 Hz<br /> 1.1 Hz 120<br /> <br /> <br /> <br /> <br /> Z "( .cm 2)<br /> Z"( .cm 2)<br /> <br /> <br /> <br /> <br /> 60<br /> 100<br /> <br /> 80<br /> 40<br /> 0V 60<br /> -0.5V<br /> -0.2 V<br /> 20 236 Hz -0.3 V 40 -0.6V<br /> -0.4 V 236Hz -0.7V<br /> 50k 20 50k -0.8V<br /> 0 0<br /> 0 20 40 60 80 100 120<br /> 0 20 40 60 80 100 120 140 160 180 200 220<br /> 2<br /> Z'( .cm ) 2<br /> Z'( .cm )<br /> a) b)<br /> Figure 2: EIS spectra in Nyquist plot for poly(JUG-co-JUGA) film in PBS solution at different<br /> potentials: a) from 0 to -0.4V; b) from -0.5 to -0.8 V (vs.SCE)<br /> <br /> Table 1: Values of parameters of equivalent circuit in function of applied potentials<br /> <br /> E, V/SCE Re/f, .cm2 Ce/f, F.cm-2 Cd, F.cm-2 Dd×10-10, cm2.s-1 Rt, .cm2<br /> -0.7 V 26.0 0.8 8 2.3 194.8<br /> -0.6 V 29.0 1.0 12 2.5A 185.1<br /> -0.5 V 28.0 1.2 16 2.5 151.1<br /> -0.4 V 31.6 1.6 50 2.0 204.2<br /> -0.3 V 30.6 1.7 22.4 1.7 225.6<br /> -0.2 V 34.0 2.0 30 1.6 251.7<br /> <br /> note that diffusion coefficient Dd depends Q•- may exchange electrons at electrode-film<br /> weakly on potentials: with the film thickness of interface:<br /> ca. 100 nm (estimated by Scanning Electron<br /> kf<br /> Microscopy), Dd is approximately of 2.10-10 Q+ e Q<br /> cm2.s-1. Finally, the variations of charge transfer<br /> resistance in both oxidation (Fig. 4a) and kb<br /> reduction (Fig. 4b) cycles go through a The faradic current is calculated from the<br /> minimum at -0.5 V and -0.4 V, to which following equation:<br /> correspond perfectly the current peaks, obtained IF = F.A.(kf×CQ kb×CQ•-)<br /> in CV’s. Where IF is faradic current; F is Faraday<br /> The behavior of charge transfer resistance constant, A is surface area of electrode, kf and kb<br /> can be explained by a simple model, initially are the forward and backward reaction rates<br /> developed by Gabrielli [11] for reversible redox respectively, which follow the Tafel law: kf = k0f<br /> system. Effectively, in electroactive domain of exp(bfE); kb = k0b exp(-bbE), bf and bb are the<br /> quinone groups, the electroactive species Q and Tafel coefficients: bf = aF/RT and bb = (1-<br /> <br /> 499<br /> a)F/RT), CQ, CQ•-: the concentrations of Q and Q•-).<br /> 2.5<br /> 50<br /> <br /> <br /> <br /> 2.0 40<br /> Ce/f( F.cm )<br /> <br /> <br /> <br /> <br /> 30<br /> -2<br /> <br /> <br /> <br /> <br /> Cd ( F.cm )<br /> -2<br /> 1.5<br /> 20<br /> <br /> <br /> <br /> 1.0 10<br /> <br /> E<br /> E 0<br /> <br /> 0.5<br /> -0.7 -0.6 -0.5 -0.4 -0.3 -0.2 -0.7 -0.6 -0.5 -0.4 -0.3 -0.2<br /> <br /> E/ V(SCE) a) E/ V(SCE) b)<br /> Figure 3: Evaluation of capacities in oxidation cycle: a) Ce/f ; b) Cd<br /> 260<br /> 340 Rt<br /> Rt<br /> 240 320<br /> <br /> <br /> 220 300<br /> R ( .cm2)<br /> <br /> <br /> <br /> <br /> 280<br /> R ( .cm2)<br /> <br /> <br /> <br /> <br /> 200<br /> <br /> 260<br /> 180<br /> 240<br /> <br /> 160 E<br /> E 220<br /> <br /> <br /> 140 200<br /> -0.8 -0.7 -0.6 -0.5 -0.4 -0.3 -0.2 -0.1 0.0 -0.6 -0.5 -0.4 -0.3 -0.2 -0.1 0.0<br /> E/V (SCE) a) E/V (SCE) b)<br /> Figure 4: Evaluation of charge transfer resistance in function of potential:<br /> a) in oxidation cycle ; b) in reduction cycle<br /> <br /> When EIS measurements are performed, the<br /> 1 1<br /> electrode potential is perturbed by a small Hence: Rt = K. + . Charge transfer<br /> sinusoidal amplitude ( E.exp(j t)). The k f kb<br /> corresponding faradic current is equal to: resistance evaluation in function of potential<br /> leads to investigate the following equation:<br /> IF = R . E + IF = R . E + F.A.(kf×CQ<br /> t<br /> -1<br /> t<br /> -1<br /> <br /> kb×CQ•-) dRt<br /> = K(-kf0.E.bf.exp(bfE) + kb0.E.bb.exp(-bbE))<br /> Where charge transfer resistance is determined dE<br /> by the following equation: With the extreme conditions: E + , kf<br /> 1<br /> Rt-1 = F.A.(bf×kf×CQ + bb×kb×CQ•-) = + Rt ;E kb + Rt<br /> kb<br /> F 2 . A k f .kb 1<br /> .C* (with C* = CQ + CQ•-)<br /> RT k f + kb kf<br /> <br /> 500<br /> i.e. Rt = f(E) pass through a minimum. 4. C. Ho, I. D. Raistrick, R.A. Huggins, J.<br /> Electrochem. Soc., Vol. 127, No. 2, P. 343<br /> IV - CONCLUSION (1980).<br /> 5. S. H. Glarum, J. H. Marshall. J.<br /> In this study, AC impedance was used for Electrochem. Soc., Vol. 127, P. 1467<br /> electrochemical study of thin polymer film with (1980).<br /> electroactive quinone group in aqueous<br /> medium. The parameter evaluations as functions 6. W. J. Albery, C. M. Elliot, A. R. Mount. J.<br /> of potentials are discussed. Especially, the Electroanal. Chem., Vol. 288, 15 (1990).<br /> variation of charge transfer is in good 7. M. F. Mathias, O. Haas. J. Phys. Chem.,<br /> agreement with the data obtained by other Vol. 96, P. 3174 (1992).<br /> methods (CV, DPV), is well explained by a 8. M. A. Vorotyntsev, C. Deslouis, M. M.<br /> simple kinetic model. Musiani, B. Tribollet, K. Aoki,<br /> Electrochimica Acta, Vol. 44, No. 12, P.<br /> REFERENCES 2105 - 2115 (1999).<br /> 9. M. C. Pham, L. D. Tran, B. Piro, T. Le<br /> 1. A. J. Bard, L. R. Faulkner. Doan, L. H. Dao. Anal. Chem. ACS 2003,<br /> Electrochemistry: Principe, Method and AC034770F, accepted for publication.<br /> Applications. John Wiley&Sons Inc (2001).<br /> 10. H. Takenouti. Programme Ariane. exe -<br /> 2. J. R. Macdonald. Impedance spectroscopy. lanceur de programme Simplexe. UPR15,<br /> New York: Wiley (1987). CNRS, 1998, Paris, France.<br /> 3. J. E. B. Randles. Disc. Farad. Soc., Vol. 1, 11. C. Gabrielli, O. Haas, H. Takenouti. J. Appl.<br /> P. 11 (1947). Electrochem., Vol. 17, P. 82 - 90 (1987).<br /> <br /> <br /> <br /> <br /> 501<br />
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