{Redox mediation at poly(o-aminophenol) coated electrodes: mechanistic diagnosis from steady state polarization curves}


doi:10.5599/jese.582  271 

J. Electrochem. Sci. Eng. 8(4) (2018) 271-280; DOI: http://dx.doi.org/10.5599/jese.582 

 
Open Access : : ISSN 1847-9286 

www.jESE-online.org 
Original scientific paper 

Redox mediation at poly(o-aminophenol) coated electrodes: 
mechanistic diagnosis from steady state polarization curves 

Gabriel Ybarra1,, Carlos Moina1, María Inés Florit2, Dionisio Posadas2 
1Instituto Nacional de Tecnología Industrial, Av. Gral. Paz 5445, CC 157, WAB1650B San Martín, 
Argentina 
2Instituto de Investigaciones Fisicoquímicas Teóricas y Aplicadas (INIFTA), Facultad de Ciencias 
Exactas, Universidad Nacional de La Plata, Suc. 4, CC 16, (1900) La Plata, Argentina 

Corresponding author - E-mail: gabriel@inti.gov.ar; Tel./Fax: +51-11-4724-6333 

Received: March 7, 2018; Accepted: March 12, 2018 
 

Abstract 
In this work, the mediated reduction of Fe(CN)63- and Fe3+ in poly(o-aminophenol) coated 
electrodes is analyzed by means of a diagnosis diagram based on the features of the 
steady state current-potential curves. This analysis allows to identify the current 
determining process and to reproduce the experimental characteristics of the polarization 
curve from the relevant kinetic and thermodynamic parameters with a minimum amount 
of experimental measurements.  

Keywords 
Current rectification; diagnostic diagrams; electroactive polymers; redox polymers 

 

Introduction 

Redox mediation is a process of indirect electron transfer between a redox species in solution 

and an electrode with the necessary participation of a third actor, a redox mediator [1-5]. Redox 

mediators can be surface immobilized sites which can be oxidized or reduced electrochemically by 

controlling the potential of the supporting electrode. The redox sites of the mediator may then 

oxidize or reduce other redox species in the solution. Direct oxidation or reduction at the electrode 

surface can be inhibited either because of intrinsically slow heterogeneous electron transfer kinetics 

or because close approach of the soluble redox species to the electrode is prevented. Redox 

polymers, such as poly(o-aminophenol) (PAP) [2] and Os(II) bipyridyl polyvynilpyridine [6], can act 

as this kind of surface-immobilized redox mediators.  

Redox mediation has attracted the attention of many researchers [4-15], mainly because the 

possibility of tuning the electrochemical reactivity of the coated electrode towards a specific end, 

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J. Electrochem. Sci. Eng. 8(4) (2018) 271-280 POLY(o-AMINOPHENOL) COATED ELECTRODES 

272  

both by choosing appropriate redox mediators and by controlling the film characteristics. It is also 

possible to design mediators with certain specific properties, such as ion selectivity, conductivity, 

formal potential, etc. 

Several models have been developed to explain the obtained i-E curves and the mechanism of 

mediation. Most of them employ the limiting current obtained in steady state conditions as the only 

criteria to determine the current determining process. In a previous work [1], we have presented a 

model, based on the previous work of Laviron [16] and Murray [17], which allows to interpret most 

of the experimental facts, as well as to elaborate diagnostic criteria from which the kinetic 

parameters can be estimated. In this work, we show how those diagnostic criteria can be applied to 

the case of the reduction of Fe(CN)63- and Fe3+ mediated by a redox polymer. The approach 

presented here provides a considerable knowledge of the system’s electrochemical behavior with a 

minimum amount of measurements. 

Experimental  

Analytical grade chemicals were used as received. The solutions were prepared with water 

purified from a Millipore Milli-Q system. The working electrode was an Au disk with a diameter of 

5.0 mm. A PAR Model 273A potentiostat was used for the voltammetric measurements. The counter 

electrode was a Pt foil of about 5.0 cm2. A 1.0 M NaCl normal calomel electrode was used as a 

reference electrode and the values of the electrode potential were converted to the saturated 

calomel electrode (SCE) scale. The polymeric films were electropolymerized as indicated elsewhere 

[2] and all measurements were carried out using 0.1 M HClO4 as supporting electrolyte. Films of 

different thicknesses were obtained by increasing the electropolymerization time. The charge under 

the cathodic peak was employed as a measure of the polymer thickness according to a relation 

obtained by ellipsometry [18].  

Theoretical framework 

We have presented elsewhere [1] a model based on previous treatments [16,17] to analyze 

current-potential curves of redox mediation at redox polymers coated electrodes. This model 

considers that any observed current under steady state conditions follows the process schematically 

shown in Figure 1.  
 

R

Oe

R

O
k

a 

electrode film solution



 

 

 


k

d,O

k
d,R

k
c

D
e
/L

x = Lx = 0  
Figure 1. Schematic representation of the mediation process in redox polymer coated electrodes. 

Oxidized (O) or reduced (R) redox species in solution must reach the polymer-solution interface 

where an electron transfer reaction takes place with the redox sites in the polymer (ω and ρ stand 

for the oxidized and reduced species in the polymer). In the solution, species O and R are 

transported to and from the polymer-solution interface. In steady state conditions, this is usually 

carried out by controlling the fluxes of O and R with a rotating disk electrode (RDE). After the 

electron exchange reaction at the polymer-solution interface takes place, charge is transported in 



G. Ybarra et al. J. Electrochem. Sci. Eng. 8(4) (2018) 271-280 

doi:10.5599/jese.582 273 

the polymer film by electron hopping, which can be described as a diffusion process. Finally, there 

is another electron transfer reaction at the polymer-electrode interface, which is assumed to be fast 

enough as not to be the current determining process. This model is limited to cases were redox 

species in solution do not penetrate significantly inside the polymer film and can be ascribed to S 

mechanisms in the Albery’s treatment [18]. 

As has been show before by Laviron [16], there are no thermodynamic restrictions for redox 

mediation by redox polymers. Nevertheless, coating the electrode with a redox polymer introduces 

additional processes for the reduction and oxidation of redox agents in solution and, consequently, 

the i-E responses of coated electrodes may differ considerably from those obtained in naked 

electrodes.   

Let us begin considering the electron exchange reaction taking place at the polymer-solution 

interface:  

 + O ⇌  + R  (1) 

whose equilibrium constant can be expressed as a function of the formal electrode potentials of 

both redox couples, E°’O/R and E°’/, as: 

o' o'
O/R ω/ρR

O

ω
exp

ρ /

E EC
K

C RT nF

 
    

 
 (2) 

Unless the value of E°’O/R is close to that of E°’/, the equilibrium constant will have either a 

considerably high or a considerable low value and therefore Eq. 1 will be displaced towards the left 

side (reactants) or the right side (products). We will focus here on mediation processes with high 

equilibrium constants, as they apply to the cases which will be presented in the Results and 

Discussion section.  

A high equilibrium constant (K1) implies that the reduction of O is greatly favored from a 

thermodynamic point of view. However, the kinetics of the redox mediation process involves several 

steps and the actual i-E response is determined by all the processes shown in Figure 1. Each of these 

steps is characterized by parameters which can be expressed as characteristic current values: 

S
OOd,Od, CnFAki   (3) 

S
Rd,Rd,R CnFAki   (4) 

LCnFADi /Tee   (5) 

S
OTckc CCnFAki   (6) 

S
RTaka CCnFAki   (7) 

id,R and id,O are related to the transport rate of redox species O and R in solution, ika and ikc to the 

charge transfer reaction rate at the polymer-solution interface and ie to the electronic transport rate 

in the polymer. COS and CRS are the concentration of O and R at the bulk of the solution and CT = C 

+ C, the total concentration of redox sites in the mediator (a complete list of symbols is given at the 

end of the article).  

With these five characteristic current parameters, a general relationship for i-E curve under 

steady state can be worked out: 



J. Electrochem. Sci. Eng. 8(4) (2018) 271-280 POLY(o-AMINOPHENOL) COATED ELECTRODES 

274  

 ka kc
e d,R e d,O

1 1 1
i i i i

i i i
i i i i

 
      

               
      

 (8) 

where  = C0/CT is the fraction of oxidized mediator at the metal-polymer interface.  

We may consider that any of the three processes schematically shown in Figure 1 can be the one 

determining the limiting current. We will denominate case R to the conditions in which the electron 

transfer at the polymer-solution interface is the current determining process (c.d.p.), case E to the 

one which is controlled by slow charge transport in the film, and case D to the one which is 

determined by slow mass transport in the solution.  

In all cases, the resulting i-E curve obtained from Eq. 8 has the usual sigmoidal shape. However, 

its location in the potential scale may vary between Eo’O/R and Eo’/, and the limiting current may 

vary from null to a certain value which is related to the most sluggish process(es) from those shown 

in Figure 1. It is interesting to note that the identification of the c.d.p. can be achieved with a 

minimum of experimental measurements (as few as two) by observing the influence of the film 

thickness on the value of the half-wave potential E½ and the limiting current. Figure 2 shows the 

diagnostic flow chart which has been worked out to identify the c.d.p. 

 
Figure 2. Diagnostic flow chart based on the consideration of half-wave potential and the film thickness for 
the mediation of the reduction of an oxidized agent under the conditions stated in the upper right square. 

It is also possible to construct a kinetic diagram, such as the one shown in Figure 3, similar to 

others previously reported [16]. This kind of diagrams is useful to visualize how experimental 

variables, such as the concentration of the external redox couple, film thickness and rotation 

frequency, affect the overall process of mediation. These plots are constructed using characteristic 

parameters of the system. We have chosen to plot log (ikc/ie) as a function of log (ikc/id,O) as shown 



G. Ybarra et al. J. Electrochem. Sci. Eng. 8(4) (2018) 271-280 

doi:10.5599/jese.582 275 

in Figure 3. For instance, the effect of increasing the film thickness is to slow down the charge 

transport in the film and correspond to a vertical displacement in the kinetic diagram. Therefore, 

R→E or D→E transitions could be observed by increasing the film thickness. Likewise, increasing 

the rotation frequency of the rotating disk electrode is associated to a horizontal displacement, and 

D→R or D→E transitions are to be expected. The use of the diagrams such as those presented in 

Figure 2 and 3 provide a straightforward insight into the mediation processes of different systems 

as is shown in the next section. 
 

 
Figure 3. Kinetic scheme showing the three different regions of control of the limiting current. 

Results and discussion 

We will begin considering the PAP|Fe(CN)63-/4- system. Figure 4a shows the steady state current-

potential curves obtained for the redox couple Fe(CN)63-/4- in 0.1 M HClO4 for a naked and a PAP-

coated electrode with different thickness at a constant rotation frequency. Both cathodic and anodic 

currents can be observed in the naked electrode, and the limiting current value corresponds to that 

obtained for the diffusion of species in solution. On the contrary, only the cathodic wave, which 

corresponds to the reduction of Fe(CN)63-, can be observed in PAP coated electrodes and it is 

displaced towards more negative potentials when compared to the naked electrode. Besides, it can 

be seen that the limiting current depends on the film thickness.  

We will interpret the obtained results within the frame of the diagnostic flow chart based on the 

half-wave potential value. The formal potential of the quasi-reversible couple in the redox polymer 

PAP has been estimated to be +0.050 V vs. SCE [2]. It can be seen in Figure 4a that PAP-coated 

electrodes present only the cathodic wave and that the half-wave potential is displaced towards 

more negative values as compared with the curve obtained in naked electrodes. In fact, the E½ 

obtained with the coated electrode coincides with the value of the formal potential of PAP. It can 

also be seen that the limiting current depends on the film thickness; the thicker the film, the lower 

the limiting current. Based on these features of i-E curve and following the diagnosis diagram (Figure 

2), we reach the conclusion that the electron transport within the film is the current determining 

step (case E). 



J. Electrochem. Sci. Eng. 8(4) (2018) 271-280 POLY(o-AMINOPHENOL) COATED ELECTRODES 

276  

 
Figure 4. (a) Experimental steady state i-E curves obtained in a 5 mM Fe(CN)63- + 5 mM Fe(CN)64- + 

+ 0.1 M HClO4 solution for a Au pristine electrode (□) and coated with PAP with a thickness of 88 nm (○) and 
125 nm (), at a rotation frequency of 1200 rpm. Full lines show simulated i-E curves. (b) Levich plot for a 
pristine (––) and PAP coated Au electrode with different film thickness: 163 nm (□), 88 nm (), 51 nm (○), 

obtained in a 5 mM Fe(CN)63- + 5 mM Fe(CN)64- + 0.1 M HClO4 solution. 

A Levich plot obtained for films with three different thicknesses is shown in Figure 4b. As can be 

seen, the limiting current increases linearly at low rotation frequency and reaches a constant value 

for a given thickness. This behavior can be explained by considering that the c.d.p. is the diffusion 

of Fe(CN)63- in the solution at low rotation frequency and then the c.d.p. is the electronic transport 

in the polymer film at high rotation frequency. The transition between both regimes is abrupt. As 

long as Fe(CN)63- flux does not exceed the electron transport capacity in the film, the limiting current 

will equal the limiting current observed in naked electrodes; once it is exceeded, the limiting current 

equals the electron transport current, ie from Eq. 5.  

It is possible to simulate i-E curves by employing Eq. 8 and the values of characteristic currents 

(ie, id,O and id,R) as experimental parameters. Being the kinetics of electron transfer much faster than 

diffusion process, kinetic parameters can be neglected from Eq. 8 (ik>>ie, ik>>id); electron transport 

characteristic current values can be obtained from Figure 4b (ie = 0.341 mA and ie = 0.524 mA for 

the thickest and the thinnest films, respectively); finally, diffusion characteristic current can be 

obtained from measurements carried out on naked electrodes (id,O = 0.698 mA and id,R = 0.625 mA). 

These parameters, together with the value of the formal potentials for PAP and Fe(CN)63-/4- couples, 

are enough to simulate the i-E curve. The simulated curves are shown in Figure 4a.  

Let us now consider the PAP|Fe3+/2+ system, with 5 mM Fe3+/2+ as the external redox couple in a 

0.1 M HClO4 solution. The redox couple has a formal potential of E°’(Fe3+/2+) = +0.510 V vs. SCE. The 

i-E curves are shown in Figure 5a, both for naked and PAP-coated electrodes. The i-E response for 

PAP-coated electrodes shows no anodic currents and the cathodic limiting current is independent 

of the film thickness.  

Figure 5a shows the steady state i-E curves for the reduction of Fe3+ in 0.1 M HClO4 obtained for 

an Au electrode and a PAP coated electrode at the same rotation frequency. At first sight, the 

features of these curves are quite similar to those found for the reduction of Fe(CN)63-, with a 

displacement of the cathodic wave towards more negative potential. We will employ the diagnosis 

criteria based on the half-wave potential to sort out the mechanism.  



G. Ybarra et al. J. Electrochem. Sci. Eng. 8(4) (2018) 271-280 

doi:10.5599/jese.582 277 

    
Figure 5.(a) Experimental steady state i-E curves obtained in a 10 mM Fe(III) + 0.1 M HClO4 solution 

for a Au pristine electrode (○) and coated with PAP of 116 nm (up triangle) y 249 nm (down triangle),  

at a rotation frequency of 300 rpm. Full lines show simulated i-E curves.  

(b) Koutecky-Levich plot for PAP coated electrodes in a 10 mM Fe(III) + 0.1 M HClO4 solution.  

Film thickness:  43 nm (□), 116 nm (), 249 nm () and 117 nm (○) 

 

Firstly, it can be noted that the half-wave potential has the same value of the PAP redox couple. 

Secondly, the limiting current is insensitive to the film thickness. Keeping this in mind, we may now 

follow the diagnosis diagram and reach to the conclusion that i-E curve is a typical Case R where the 

c.d.p. is the electron transfer reaction between the polymer and the redox species. 

The Koutecky-Levich plots, ilim,cat-1 vs. -1/2 (Figure 5b), provide additional information for systems 

which can be ascribed to Case R. It can be shown from Eq. 8 that, under circumstances that apply in 

this case, the origin ordinate equals ikc-1. As was done with the PAP|Fe(CN)63-/4- system, the i-E curve 

can be simulated employing as experimental parameters the value of the characteristic current for 

the electron transfer kinetics (ikc-1) and the diffusion one (id,R), and the formal potential for the PAP 

couple and the Fe2+/3+ redox couple (see Figure 5a). 

Finally, it worth noting that it is possible to locate both studied systems PAP|Fe3+/2+ and PAP| 

Fe(CN)63-/4- in a kinetic diagram, employing estimated values for the kinetic constants and diffusion 

coefficients [2]. The axis in the kinetic diagram corresponds to non-dimensional parameters formed 

by constants (electron transfers constant, diffusion coefficient) and variables (frequency of rotation of 

the RDE, film thickness). While the involved constants depend exclusively on the system under study, 

variables can be modified within a certain range. Thus, there is a window accessible for any given 

system. In Figure 6 we show the estimated windows for both systems. In the case of the PAP|Fe3+/2+ 

system, electron transfer at the polymer-solution interface is so sluggish that this process will always 

have a determining influence on the observed current (case R). On the contrary, for the 

PAP|Fe(CN)63-/4-, the electron transfer is so rapid that other processes will limit the current: either the 

transport of redox agents in solution (case D) or the electron transport in the polymer film (case E). As 

a matter of fact, it is possible to move from one regime to the other by controlling the experimental 

variables. We may change from case D to case E either by increasing the rotation frequency (i.e. 

moving horizontally in the kinetic diagram) or by increasing the film thickness (moving vertically in the 

kinetic diagram). In both cases, the transition is abrupt, as shown in Figure 4b. 



J. Electrochem. Sci. Eng. 8(4) (2018) 271-280 POLY(o-AMINOPHENOL) COATED ELECTRODES 

278  

 
Figure 6. Localization in the kinetic diagram for the reduction of Fe(III) species in the two PAP-Fe(II/III) 

systems presented in this work. 

Conclusions 

In this work we have analyzed the i-E response of a redox polymer (PAP) modified electrode in 

steady state towards the mediated reduction of Fe3+ and Fe(CN)63-. The available set of diagnostic 

criteria is widened with the addition of the position of the half-wave potential. We have shown that 

the analysis of the complete curve allows identification of current determining process, to obtain 

the kinetic and transport parameters and to simulate the experimentally obtained current-potential 

curves with a set of characteristic current values which can be easily assessed.  

Acknowledgements: This work was financially supported by the Consejo Nacional de Investigaciones 
Científicas y Técnicas, the Agencia Nacional de Promoción Científico Tecnológica, the Universidad 
Nacional de La Plata, the Comisión de Investigaciones Científicas de la Provincia de Buenos Aires and 
the Instituto Nacional de Tecnología Industrial. M. I. F. and D.P. are members of the CIC and CONICET. 

List of symbols 

 fraction of oxidized redox sites 

 reduced redox site in the polymer 

 oxidized redox site in the polymer 

 electrode rotation frequency 

A electrode area 

C concentration 

D diffusion coefficient 

E electrode potential 

E°' formal potential  

E½ half-wave potential 

F Faraday constant 

ie characteristic electronic current 

id characteristic diffusion current 



G. Ybarra et al. J. Electrochem. Sci. Eng. 8(4) (2018) 271-280 

doi:10.5599/jese.582 279 

ik characteristic kinetic current 

ilim limiting current 

K electron transfer rate constant 

K equilibrium constant 

L film thickness 

N number of exchanged electrons 

O oxidized species in solution 

R reduced species in solution 

R gas constant 

T absolute temperature 

x distance from the electrode-polymer interface 

  

 Subscripts and superscripts 

0 metal-polymer interface 

A anodic 

C cathodic 

Eq thermodynamical equilibrium condition 

D diffusion 

E electronic 

L polymer-solution interface 

O soluble oxidized species 

R soluble reduced species 

S solution 

T total redox sites 

  

 Current determining processes 
Case E control by slow electron transport in the polymer 
Case D control by slow soluble species diffusion in the solution 

Case R control by slow electron transfer reaction between soluble species and redox species 
in the polymer 

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