Influence of various metallic oxides on the kinetic of the oxygen evolution reaction on platinum electrodes


doi:10.5599/jese.157  79 

J. Electrochem. Sci. Eng. 5(2) (2015) 79-91; doi: 10.5599/jese.157 

 
Open Access : : ISSN 1847-9286 

www.jESE-online.org 

Original scientific paper 

Influence of various metallic oxides on the kinetic of the oxygen 
evolution reaction on platinum electrodes 

Kambire Ollo, Pohan Lemeyonouin Aliou Guillaume, Appia Foffié Thiéry Auguste, 
Gnamba Corneil Quand-Meme, Kondro Konan Honoré, Ouattara Lassiné 

Laboratoire de Chimie Physique, UFR SSMT, Université Félix Houphouët-Boigny de Cocody, Abidjan, 
22 BP 582 Abidjan 22, Côte d’Ivoire 

Corresponding Author: ouatlassine@yahoo.fr ; Tel: +22502143382 

Received: December 23, 2014; Revised: April 13, 2015; Published: August 26, 2015 
 

Abstract 
Pt, 50Pt-50RuO2 and 50Pt-50IrO2 electrodes were prepared on titanium (Ti) substrate by 
thermal decomposition techniques. The micrographs of 50Pt-50RuO2 and 50Pt-50IrO2 have 
revealed that their surfaces are rough with cracked structures in contrast to platinum 
which exhibits smooth, compact and homogeneous surface. The richer the electrode 
surface in platinum, thinner is the crack size and also more compact is the electrode 
surface. The electrodes have also been characterized electrochemically by cyclic 
voltammetry in acidic (HClO4) and alkaline (KOH) electrolytes. These characterizations 
showed that the surface of the 50Pt-50RuO2 and 50Pt-50IrO2 electrodes were composed of 
platinum and metal dioxide active sites. The Tafel slope obtained on Pt, 50Pt-50RuO2 and 

50Pt-50IrO2 for the oxygen evolution reaction (OER) were respectively 120, 90 and 
44 mV dec

-1
 in acid electrolyte. In the alkaline electrolyte, they were 119, 87 and 

42 mV dec
-1

 on Pt, 50Pt-50RuO2 and 50Pt-50IrO2 electrodes, respectively, indicating that for 
the prepared electrodes, Tafel slopes are the same in acidic and in alkaline media. 
Moreover, in acidic and in alkaline media, the kinetic of the oxygen evolution reaction 
was faster on 50Pt-50RuO2 and 50Pt-50IrO2 than Pt owing to a synergetic effect of Pt and 
the oxides. That additional effect of the surface component 50Pt-50RuO2 and 50Pt-50IrO2 
electrodes let them possess higher electrocatalytic activity towards OER than Pt in the 
two media. Though the kinetic of the oxygen evolution reaction is practically the same in 
acidic and alkaline media for all the electrodes, OER occurred at lower overpotential in 
alkaline electrolyte than in acidic electrolyte on the prepared electrodes. 
 

Keywords 
Platinum, Ruthenium dioxide, Iridium dioxide, Tafel slope, Cyclic voltammetry, Electrocatalytic 
activity, Oxygen evolution reaction 

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J. Electrochem. Sci. Eng. 5(2) (2015) 79-91 KINETIC OF THE OXYGEN EVOLUTION REACTION 

80  

Introduction 

Oxygen evolution reaction (OER) has been extensively studied in electrochemistry because of 

its importance in many fields such as fuel cells, wastewater treatment, chlorine evolution, 

corrosion, water electrolysis [1-7]. OER reaction kinetics and mechanism aspects drew a great 

attention and still continue to be investigated. Because of the use of electrochemistry to solve 

environment pollution problems [8-10], a particular interest was directed towards the search of 

better electrocatalysts that could lead to a decrease of the OER overpotential. In the above 

mentioned field, platinum played an important role because of its good electronic and corrosion 

resistance properties. Although platinum is known to be one of the best electrocatalyst in acidic 

electrolytes, its high cost requires its replacement with new materials. Used for the oxidation of 

organics such as methanol and ethanol, platinum undergoes electrode fouling consequently 

reducing its electrooxidation activities. Since it is known that OER depends mainly on chemical and 

structural properties of electrode materials surface, our interest was focused on platinum and 

transition metal oxide modified platinum electrodes. Indeed, since the discovery of 

Dimensionnally stable anodes (DSAs) by Beer around 1970, a lot of research efforts were made on 

such kind of electrodes in relation to a variety of processes has been carried out including OER. It 

has been shown that among the DSAs, iridium dioxide and ruthenium dioxide exhibit good OER 

performance. In prior investigation in our team, it has been shown that combining 50 % molar 

ratio of Pt and metallic oxides led to higher activity for organic oxidations [11]. The aim of the 

present study was to investigate the electrocatalytic activity and the kinetics of the OER on the 

same kind of electrode i.e. platinum modified with various transition metal oxides. 

Experimental 

The electrodes used in the following work were all prepared in our laboratory with appropriate 

metallic precursors. The coating precursors were prepared from H2PtCl6,6H2O (Fluka), RuCl3,×H2O 

(Fluka) and H2IrCl6,6H2O (Fluka). All the precursors were dissolved in pure isopropanol (Fluka) used 

as solvent. The commercial products were used as received without any further treatment.  

The titanium substrates on which the electrode films were deposited have the following 

dimension 1.6 × 1.6 × 0.5 cm. The surface of each substrate was sandblasted to ensure good 

adhesion of the deposit on it. After, sandblasting, all the substrates were washed vigourously in 

water and then in isopropanol to clean their surface from residual sands. The substrates were then 

dried in an oven at 80 C and weighed. After that, the precursor was applied by a painting 

procedure on the titanium (Ti) substrate then put in an oven for 15 min at 80 °C in air to allow the 

solvent evaporation. Then after, it is put in a furnace at 400 °C for 15 min in air to allow the 

decomposition of the precursor. Theses steps were repeated until the desired  mass of the coating 

is reached. A final decomposition of 1 h was done at 400 °C. The electrodes prepared by this 

technique are platinum (Pt), platinum-iridium dioxide (50Pt-50IrO2) and platinum-ruthenium dioxide 

(50Pt-50RuO2) electrodes. For the combined electrodes, a mixture of 50  % molar ratio of the 

corresponding precursor was used. The deposit loading was about 5 g m
-2

 on each titanium 

substrate. 

The physical characterization of the electrodes were performed using a scanning electronic 

microscopy (SEM, ZEISS, SUPRA 40VP) device.  

The voltammetric measurements were performed under either 1 mV s
-1

 or 100 mV s
-1

 on the 

prepared electrodes in a three-electrode electrochemical cell using an Autolab PGStat 20 

(Ecochemie). The counter electrode (CE) was a platinum wire and the reference electrode (RE) was 



K. Ollo et al. J. Electrochem. Sci. Eng. 5(2) (2015) 79-91 

doi:10.5599/jese.157 81 

a saturated calomel electrode (SCE). All the potential were reported against SHE according to the 

following relation: E / V vs. SHE = E / V vs. SCE + 0.25. To decrease the contribution of ohmic losses, 

the reference electrode was mounted in a luggin capillary and placed close to the working 

electrode by a distance of 1 mm. In fact, ohmic drop is known to increase the value of the Tafel 

slope and careful attention was to be paid on it during experiment. In order to reduce totally the 

residual ohmic drop, the polarization curve should be corrected according to method described 

elsewhere [12-15]. A brief description of the correction is given as followed.  
The overpotential η / V observed in the experiment can be given by  

  η / V=a + b lnj+jR  (1) 

where a / V is the Tafel constant, b / V dec
-1

 is the Tafel slope, j / A cm
-2

 is the current density and 

R /  cm
-2

 is the total area-specific uncompensated resistance of the system, which is assumed to 

be constant. The derivative of equation (1) with respect to current density gives equation (2) from 

which b and R can be easily obtained by plotting dη / dj as a function of 1/j 

d

d

b
R

j j


   (2) 

The estimation of R allows correcting the experimental overpotential by substracting the ohmic 

drop jR according to equation (3) 

ηcorr = η – jR (3) 

where ηcorr stands for the corrected overpotential 

During the calculations, the derivatives dη⁄dj was replaced by their finite elements Δη⁄Δj 

estimated from each pair of consecutive experimental points. 

The apparent exposed area of the working electrode was 1 cm
2
. 

For the electrochemical investigations HClO4 (Fluka), KOH (Fluka) were used as received for the 

preparation of the solutions employed in that work with distilled water. All the experiments were 

made at ambient temperature of 25 °C. 

Results and discussion 

Physical characterization of the prepared electrodes 

In Figure 1, the micrographs of the prepared electrodes were presented. It appears that the 

surface was totally covered by the deposit. The surface of the platinum electrode seems to be 

smooth, compact and almost homogeneous (Figure 1a). The surface of 50Pt-50RuO2 (Figure 1b) is 

rough and seems to be compact as that of platinum but cracks were observed like those of DSA’s 

[16,17]. Such finding indicated that the electrode surface of the 50Pt-50RuO2 electrode is composed 

by platinum and ruthenium dioxide. In Figure 1c, the prepared 50Pt-50IrO2 electrode is shown and 

its surface presents almost the same characteristic as 50Pt-50RuO2 but in this case, the electrode 

surface is highly rough with more cracks. The size of the cracks are thinner as generally observed 

at such magnification for pure DSAs possibly due to the presence of platinum which contributes to 

render the combined electrode surface to have compact structures.  
 

 

 

 



J. Electrochem. Sci. Eng. 5(2) (2015) 79-91 KINETIC OF THE OXYGEN EVOLUTION REACTION 

82  

a 

 
b 

 
c 

 
Figure 1: Scanning electron micrographs of Pt(a), 50Pt-50RuO2(b) and 50Pt-50IrO2(c) 

Electrochemical characterization of the electrodes in perchloric acid medium 

Cyclic voltammetric measurements were performed on a platinum electrode in perchloric acid 

1 M under a scan rate of 100 mV s
-1

 and the results were depicted in Figure 2a. The figure showed 

the usual feature generally observed with polycrystalline platinum in acidic media [18]. Well 

defined adsorption and desorption peaks located in the potential domain between 0 and 0.4 V 



K. Ollo et al. J. Electrochem. Sci. Eng. 5(2) (2015) 79-91 

doi:10.5599/jese.157 83 

were shown. The double layer region characterized by an almost zero current in the forward 

potential scan followed by oxide formation domain (0.74 V-1.51 V) and an oxide reduction peak at 

0.72 V (backward potential scan) were also presented. A rapid increase in the current related to 

OER started at 1.51 V. 

In Figures 2b and 2c, the voltammograms resulted from the investigation made on the platinum 

modified electrodes were presented. For such investigation, 50Pt-50IrO2 and 50Pt-50RuO2 have been 

used. As a general response, the modified electrodes led to voltammograms resembling to that 

obtained with pure platinum electrode. That result indicated that the surface of the modified 

electrodes is partly composed of platinum clusters. The voltammetric charges of the combined 

electrodes are higher than that of platinum. That is due to the presence of metal oxides on the 

electrode surface. The voltammogram of the 50Pt-50RuO2 electrode presents a feature that bears 

more resemblance to that of platinum than the voltammogram of 50Pt-50IrO2 compared to that of 

platinum. That result indicated that RuO2 has more electronic and structure affinity with platinum 

than IrO2 towards platinum. It can also be deduced from those results that 50Pt-50RuO2 surface is 

composed of much platinum clusters due to its migration from the inside of the coating to its 

surface during the thermal decomposition of the precursor. But in case of 50Pt-50IrO2, a hindering 

effect of IrO2 on platinum migration occurs that results in lower spread of platinum on such 

composite electrode surface. Although this observation is made, presence of metal oxide and 

platinum on the electrode surface showed synergetic effect i.e. increasing in active sites than 

platinum used alone. In the high potential domain, using oxygen evolution as a probe reaction to 

investigate the electrocatalytic activity of the prepared electrodes, it appeared that the onset of 

the potential at the increase in current are 1.43 V; 1.41 V and 1.51 V on 50Pt-50RuO2, 50Pt-50IrO2 and 

Pt respectively. From these results, it appears that 50Pt-50IrO2 and 50Pt-50RuO2 are more 

electrocatalytic for OER than pure platinum owing to their low overpotential for OER than pure 

platinum electrode. For the prepared composite electrodes 50Pt-50IrO2 appeared to be more 

catalytic for OER than 50Pt-50RuO2. Such result is in accordance with the above obtained result and 

is explained by the fact that the surface of 50Pt-50RuO2 is mostly composed by platinum than on 

50Pt-50IrO2 electrode. Indeed, mixing metallic oxides such as transition metal oxide led to an 

increase in the electrocatalytic behavior of platinum and/or the prepared electrode towards 

oxygen evolution reaction.  

Plotting log j versus the potential E, straight lines were obtained in the Tafel region as shown in 

Figure 3. The obtained Tafel slopes are presented in Table 1. 

It is worth noting that Tafel slopes are an indicator of electrocatalytic activity. In fact, the lower 

the Tafel slope the faster the kinetics of the reaction and the more active the electrocatalyst is. 

From Table 1, it could be noticed that pure platinum exhibits a Tafel slope of 120 mV dec
-1

 which is 

higher than those obtained on the composite electrodes. The Tafel slope of 50Pt-50RuO2 is higher 

than that of 50Pt-50IrO2. The exchange current densities have been determined (Table 1) and the 

obtained values indicated that the system O2/H2O is kinetically slow on all the investigated 

electrodes. Meanwhile, from these findings, regarding the Tafel slopes, it appears that OER is 

more rapid on 50Pt-50IrO2 than on 50Pt-50RuO2 and sluggish on pure platinum electrode. These 

results are in accordance with the above obtained results where the onset of the potential of OER 

was concerned. In fact, as the surface of the electrode is dominated by platinum clusters in the 

following order 50Pt-50IrO2 < 50Pt-50RuO2 < Pt as shown by voltammetric investigation in acidic 

medium, an increase in the Tafel slope is observed. 

 



J. Electrochem. Sci. Eng. 5(2) (2015) 79-91 KINETIC OF THE OXYGEN EVOLUTION REACTION 

84  

 

 

 
Figure 2: Cyclic voltammograms of Pt (a), 50Pt-50RuO2 (b) and 50Pt-50IrO2 (c) in 1 M HClO4  

at 100 mV s
-1

, CE: platinum, T = 25°C 

Table 1: Tafel slopes and exchange current densities of various electrodes in 1 M HClO4;  
v =1 mV s

-1
; CE : platinum; T = 25 °C 

Electrodes  Tafel slope / mV dec
-1

 Exchange current density j0 10
4
 / A cm

-2
 

Pt 120 0.728
 

50Pt-50RuO2 90 4.375 

50Pt-50IrO2 44 1.069 



K. Ollo et al. J. Electrochem. Sci. Eng. 5(2) (2015) 79-91 

doi:10.5599/jese.157 85 

 

 

 
Figure 3 : Tafel line of Pt (a), 50Pt-50RuO2 (b) and 50Pt-50IrO2 (c) in perchloric acid 1 M ;  

v =1 mV s
-1

; CE : platinum; T = 25°C 

Although the Tafel slopes delineate the rapidity of the kinetics occurring on the electrode 

surface, it is also related to the rate determining step in the OER mechanism. The electrodes 



J. Electrochem. Sci. Eng. 5(2) (2015) 79-91 KINETIC OF THE OXYGEN EVOLUTION REACTION 

86  

presented thus different rate determining steps. From the literature, a globally accepted OER 

mechanism is described as followed in acidic media [14, 19]. 

S + H2O  S-OH + H
+
 + e

-
 (4) 

S-OH   SO + H 
+
 + e

-
 (5) 

2SO  2S + O2 (6) 

where S stands for electrode active sites; OH and O represent adsorbed intermediates. 

If the step (4) is the rate determining step, current density associated with reaction (4) can be 

given as: 

   1 2 1 2H O 1
F

j kF exp
RT


   

 
    

 
 (7) 

j - current density, k - constant of the kinetic of the reaction, Γ - total active sites,  1 and 2 : rate of 

adsorbed OH and O respectively, α - charge transfer coefficient, η - overpotential 

Taking into account a second electron transfer taking place in step (5), the total faradic current 

density can be obtained through the following equation:  

   1 2 1 22 2 H O 1
F

j j kF exp
RT


  

 
      

 
 (8) 

Considering K as 

K=2kF[H2O]Γ(1-1-2 )  (9) 

(8) becomes  

exp
F j

RT K




 
 

 
.  (10) 

Then 

ln10 ln10
 log log
RT RT

j K
F F


 

   (11) 

The expression of the Tafel slope is obtained by doing  

R

a

P,T,C

ln 10
   

log| |

RT
b

j F





 
  

 
 (12) 

In the experimental condition ba= 120 mV dec
-1

. 

When each of the steps (5) and (6) is considered as a rate determining step, the corresponding 

Tafel slope would be 40 mV dec
-1

 and 15 mV dec
-1

 respectively.  

According to these results and regarding the Tafel slopes of Table 1, one can consider that the 

rate determining step occurring on the platinum electrode is related to the hydroxyl radical 

adsorption on the active sites of that electrode (step 4) since the Tafel slope is 120 mV dec
-1

. Such 

a result has been found by many other authors on platinum in acidic media [20,21]. With 50Pt-

50IrO2, a Tafel slope of 44 mV dec
-1

 was found. That result indicated that the rate determining step 

is given by equation (5) of the proposed mechanism. With 50Pt-50RuO2, the obtained Tafel slope is 

90 mV dec
-1

 which is almost close to 120 mV dec
-1

. Rate determining step is similar to that 



K. Ollo et al. J. Electrochem. Sci. Eng. 5(2) (2015) 79-91 

doi:10.5599/jese.157 87 

obtained with pure platinum but the kinetic of the OER is higher on that electrode than platinum 

owing to either a mixed kinetic control proceeding via unstable adsorption species such as S-OH* 

(Equations 13 and 14) [14,19] or the synergetic effect of the two surface components (Pt and 

RuO2).  

S + H2O  S-OH* + H
+
 +e

-
 (13) 

S-OH*  S-OH (14) 

Electrochemical characterization of the prepared electrodes in alkaline electrolyte 

In the 0.5 M potassium hydroxide electrolyte, voltammograms have been recorded on platinum 

electrode. The obtained result is depicted in Figure 4a. The trend of the curve is different to that of 

platinum in acidic medium. The voltammogram presents a rectangular shape in the potential 

window explored.  

Figures 4b and 4c show the voltammograms recorded on 50Pt-50IrO2 and 50Pt-50RuO2 electrodes. 

All the voltammograms showed almost the same feature. In the low potential domain, one 

observed superimposed voltammograms of platinum and 50Pt-50RuO2 indicating that the surface of 

50Pt-50RuO2 electrodes is rich in platinum clusters. The onset of the oxygen evolution reaction 

potential decreased highly as platinum is associated with transition metal oxides (IrO2 and RuO2). 

The obtained potential values are 0.67 V, 0.67 V and 0.78 V for 50Pt-50IrO2, 50Pt-50RuO2 and Pt 

respectively. It appears that adding transition metal oxide such as ruthenium dioxide and iridium 

dioxide to platinum leads to electrodes with a higher electrocatalytic activity towards oxygen 

evolution reaction than pure platinum electrodes. That finding is in accordance with the results 

that are obtained in acidic medium indicating that the enhancement of the electrocatalytic activity 

of the composite electrodes could be due to a synergetic effect of the two elements that exist on 

the electrode surface. 

Stability in the voltammograms was observed in that medium. That is the sign that no other 

oxide growth of the electrodes surface happened. In both media, platinum modified with IrO2 or 

RuO2 possesses the best electrocatalytic activity for OER than pure platinum. 

The Tafel slopes of the electrodes used in this study have been determined in alkaline medium. 

The ohmic drop correction has been carried out like in acidic medium. Figure 5 shows the 

measured Tafel line of the electrodes. The obtained Tafel slopes are consigned in Table 2.  
It appears that the slope decreases in the following order Pt>Pt-RuO2>Pt-IrO2 indicating that the 

rate determining steps are not the same on all the electrodes. Regarding the Tafel slopes, 50Pt-

50IrO2 seemed to behave as the best electrocatalyst for oxygen evolution reaction. In contrast, Pt 

presents the lowest electrocatalytic activity towards oxygen evolution reaction. Coupling platinum 

and iridium or ruthenium oxides helps to increase oxygen evolution kinetics. The exchange current 

densities have been determined (Table 2) and the obtained values indicated that the system 

O2/OH
-
 is kinetically low on all the investigated electrodes. It worth indicating that the same Tafel 

slope was obtained on the prepared electrodes independently of the nature of the electrolyte.  

Table 2. Tafel slopes of the prepared electrodes in KOH 0.5 M; v =1 mV s
-1

; CE : platinum ; RE : SHE ; T = 25°C 

Electrodes Tafel slope, mV dec
-1

 Exchange current density j0 10
4
 / A cm

-2
 

Pt 119 0.186 

50Pt-50RuO2 87 0.140 

50Pt-50IrO2 42 10.83 



J. Electrochem. Sci. Eng. 5(2) (2015) 79-91 KINETIC OF THE OXYGEN EVOLUTION REACTION 

88  

 

 

 

 
Figure 4. Cyclic voltammograms of Pt (a), 50Pt-50RuO2 (b) and 50Pt-50IrO2 (c) in KOH 0.5 M  

at 100 mV s
-1

, CE : platinum, T= 25°C 



K. Ollo et al. J. Electrochem. Sci. Eng. 5(2) (2015) 79-91 

doi:10.5599/jese.157 89 

 

 

 
Figure 5. Tafel line of Pt (a), 50Pt-50RuO2 (b) and 50Pt-50IrO2 (c) in KOH 0.5 M; v = 1 mV s

-1
;  

CE : platinum, T = 25°C 

Oxygen evolution reaction is known to be a complex reaction. It depends normally on many 

factors such as electrode materials, experimental condition, and electrode preparation conditions. 



J. Electrochem. Sci. Eng. 5(2) (2015) 79-91 KINETIC OF THE OXYGEN EVOLUTION REACTION 

90  

The following oxygen evolution reaction mechanism that has received much agreement among 

researchers in alkaline electrolytes is proposed as followed [22-24].  

S + OH
-
  SOH + e

- 
(15) 

SOH + OH
-
  SO

-
 + H2O (16) 

SO
-
  SO + e

-  
(17) 

2SO  2S + O2 (18) 

S represents the electrode active sites; OH, O
-
 and O represent the adsorbed intermediates.  

Assuming step (15) of that mechanism as the rate determining step, the Tafel slope determined 

theoretically was about 120 mV dec
-1

. In the case that the rate determining step is supposed to be 

step (16), the Tafel slope would be 60 mV dec
-1

. Tafel slopes are 40 mV dec
-1

 and 15 mV dec
-1

 in 

alkaline electrolyte if steps (17) and (18) were considered as rate determining steps respectively.  
Considering the platinum electrode with a Tafel slope of 119 mV dec

-1
, the rate determining step 

in the oxygen evolution process on this electrode is step (15). With 50Pt-50IrO2 the Tafel slope is 

about 42 mV dec
-1

 which is close to 40 mV dec
-1

. Thus, on this electrode, step (17) could be the 

rate determining step in the oxygen evolution reaction. For the 50Pt-50RuO2 electrode, the Tafel 

slope is 87 mV dec
-1

. As has been observed in acidic medium, that value is almost close to 

120 mV dec
-1

 indicating that platinum effect seems to dominate the totally surface effect. Step 

(15) could be the rate determining step in the OER process.  

Conclusion 

The micrographs of 50Pt-50RuO2 and 50Pt-50IrO2 have revealed that their surfaces are rough with 

cracked structures. That of platinum was smooth, compact and homogeneous. The richer the 

electrode surface in platinum, thinner is the crack size and also more compact is the electrode 

surface.  

Cyclic voltammetry investigations have revealed the presence of both IrO2 or RuO2 and Pt on 

the thermally prepared 50Pt-50RuO2 and 50Pt-50IrO2 electrode surface. The addition of metallic 

dioxide to platinum leads to electrodes with higher electrocatalytic activity than platinum towards 

oxygen evolution used as probe reaction. That electrocatalytic enhancement is due to a synergetic 

effect of the surface component. All the prepared electrodes showed different rate determining 

steps. Tafel slopes are found to be almost the same in acid and in alkaline electrolytes indicating 

the same rate determining steps for each electrode.  

Acknowledgements: We greatly thank the Swiss National Funds for its financial support that 
allowed this work to be carried out. Our Team has received part of the grant IZ01Z0_146919 for 
that work. We also thank Prof. Cesar Pulgarin at the Swiss Federal Institute of Lausanne 
(Switzerland) and Prof. Ricardo Torres at the University of Antioquia (Colombia) for their help in 
that work. 

References 

[1] G. B. Tissot, A. Anglada, P. Dimitriou-Christidis, L. Rossi, J. S. Arey, C. Comninellis, 
Electrochemistry Communications 23 (2012) 48-51. 

[2] X. D. Xiang, Q. M. Huang, Z. Fu, Y. L. Lin, W. Wu, S. J. Hu, W. S. Li, International Journal of 
Hydrogen Energy 37(5) (2012) 4710-4716. 



K. Ollo et al. J. Electrochem. Sci. Eng. 5(2) (2015) 79-91 

doi:10.5599/jese.157 91 

[3] C. C. Huang, Q. Wang, D.B. Xiang, H.B. Shao, Chinese Chemical Letters 22(12) (2011) 1481-
1484. 

[4] D. Basu, S. Basu, Electrochimica Acta, 56 (2011) 6106-6113.  
[5] S. Ferro, D. Rosestolato, C. A. Martinez-Huitle, A. De Battisti, Electrochimica Acta 146 

(2014) 257-261. 
[6] Y. Chieng, C. Xu, L. Jia, J.D. Gale, L. Zhang, P.K. Shen, S.P. Jiang, Applied Catalysis B : 

Environmental 163 (2015) 96-104.  
[7] Z. Y. Li, S. T. Shi, Q. S. Zhong, C. J. Zhang, C. W. Xu, Electrochimica Acta 146 (2014) 119-124.  
[8] E. I. Papaioannou, A. Siokou, C. Comninellis, A. Katsaounis, Electrocatalysis, 4 (4) (2013) 

375-381.  
[9] L. Ouattara, A. L. G. Pohan, Revue Ivoirienne des Sciences et Technologie 17 (2011) 1-15 

[10] B. Kouakou, L. Ouattara, A. Trokourey, Y. Bokra, Journal of Applied Sciences and 
Environmental Management 12 (4) (2008) 103-110. 

[11] K. H. Kondro, L. Ouattara , A. Trokourey, Y. Bokra, Bulletin of the Chemical Society of 
Ethiopia 22(1) (2008) 125-134.  

[12] A. Kapalka, G. Fóti, C. Comninellis, Electrochemistry Communications 10 (2008) 607-610. 
[13] G. Rocchini, Corrosion Science, 34(12) (1993) 2019-2030 
[14] L. A. De Faria, J. F. C. Boodts,  S. Trasatti, Journal of Applied Electrochemistry 26(11) (1996) 

1195-1199. 
[15] N. Krstajic, S. Trasatti, Journal of Applied Electrochemistry 28(12) (1998) 1291-1297. 
[16] L. Ouattara, T. Diaco, I. Duo, M. Panizza, G. Foti, Ch. Comninellis, Journal of the 

Electrochemical Society 150 (2) (2003) D41-D45.  
[17] F. Moradi, C. Dehghanian, Progress in Natural Science: Materials International 24 (2) (2014) 

134-141. 
[18] D. J. Walton, L. D. Burke, M. M. Murphy, Electrochimica Acta 41(17) (1996) 2747-2751. 
[19] E. Tsuji, A.  Imanishi, K. I. Fukui, Y. Nakato, Electrochimica Acta 56 (2011) 2009-2016. 
[20] V. I. Birss, A. Damjanovic, P. G. Hudson, Journal of Electrochemical Society 133(8) (1986) 

1621-1625.  
[21] G. Lodi, E. Sivieri, A. De Battisti, S. Trasatti, Journal of Applied Electrochemistry 8(2) (1978) 

135-143  
[22] C. Eun-Ok, K. Young-Uk, M. Sun-Il, Bull. Korean Chemical Society 18 (9) (1997) 972-976   
[23] C. Iwakura; K. Fukuda, H. Tamura, Electrochimica Acta 21 (1976) 501-508  
[24] I. M. Sadiek, A. M. Mohammad, M. E. El-Shakre, M. S. El-Deab, International Journal of 

Hydrogen Energy 37(1) (2012) 68-77  
 

 
 
 
 
 
 
 
 
 
 

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