{Electrocoagulation of whey acids: anode and cathode materials, electroactive area and polarization curves}


doi:10.5599/jese.381  89 

 

J. Electrochem. Sci. Eng. 7(2) (2017) 89-101; doi: 10.5599/jese.381 

 
Open Access : : ISSN 1847-9286 

www.jESE-online.org 

Original scientific paper 

Electrocoagulation of whey acids: anode and cathode materials, 
electroactive area and polarization curves 

Francisco Prieto-García1, Judith Callejas-Hernández1, Judith Prieto-Méndez2,, 
Yolanda Marmolejo-Santillán1 
1Área Académica Química, Universidad Autónoma del Estado de Hidalgo. Carret. Pachuca-
Tulancingo, km. 4.5, C. P. 42076. Mineral de la Reforma. Hidalgo. México 
2Área Académica de Agronomía, Universidad Autónoma del Estado de Hidalgo. Carret. Pachuca-
Tulancingo, km. 4.5, C. P. 42076. Mineral de la Reforma. Hidalgo. México 

Corresponding author: jud_292003@yahoo.com.mx 
Received: March 30, 2017; Revised: June 6, 2017; Accepted: June 6, 2017 
 

Abstract 
Anode (Al and Fe) and cathode (graphite and Ti/RuO2) materials have been tested for 
electrocoagulation (EC) and purification of the acid whey. The electroactive areas (EA) of 
electrodes were calculated by the double layer capacitance method. Experiments were 
performed by cyclic voltammetry, chronoamperometry and polarization experiments. 
Among cathodic materials, the Ti/RuO2 electrode showed higher EA (2167 cm2) than 
graphite (1560 cm2). The Fe anode was found more stable than Al with greater charge 
transfer carried out in less time. Correlation of these results with those obtained during 
preliminary tests confirmed high removals (79 %) in 8 h. For the Al electrode, 24 h were 
required to achieve efficiency of 49 %. 

Keywords 
Electrocoagulation, electrode materials, acid whey, electroactive area, capacitance, Tafel slopes 

 

Introduction 

The electrodes are indispensable components of any electrochemical cell because just on their 

surface the processes of oxidation-reduction of the species occur together with other reactions 

carried out during electrolysis 1,2. When an electrocoagulation (EC) process is applied, the 

electrodes must be cost-effective and easy to handle. In addition, the electrodes used as sacrificial 

anodes must also possess great dissolution power. The most frequent materials used for EC 

processes of different effluents with good removal efficiencies are aluminum (Al) and iron (Fe), but 

other materials such as steel 3,4 have also been tested. 

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J. Electrochem. Sci. Eng. 7(2) (2017) 89-101 ELECTROCOAGULATION OF WHEY ACIDS 

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In the present study, different materials acting as anodes (Al and Fe) and cathodes (graphite and 

Ti/RuO2) are tested for the EC and purification of residual acid whey. The evaluation is performed 

with respect to the electroactive electrode area and through polarization curves. 

Methodology 

Determination of electroactive area (EA) of electrodes 

Determination of real electroactive area (EA) was done for Al, Fe, graphite (G) and Ti/RuO2 

electrodes. The cyclic scanning voltammetry technique, exploring the BASI Epsilon EC potentiostat 

2.13 USB was used. Experiments were performed in 0.1 M KCl solution acidified with HCl to maintain 

pH 4.7, what simulates the initial pH of the acid whey 5,6. The electroactive area of each electrode 

surface was calculated by the capacitance of the double layer, Cdl, generated on the electrode in 

contact with an electrolyte 7. 

A glass beaker (2 L) containing 0.1 M KCl solutions was used as the electrochemical cell in which 

the electrodes were immersed (Fig. 1). The electrodes were submerged to a height of 5 cm, exposing 

a geometric area of approximately 100 cm2 to the solution. The dimensions of electrodes were as 

follows: Al (10.2  10  0.1 cm), Fe (10.1  10  0.2 cm), G (8.2  10  1.2 cm) and Ti/RuO2 mesh 

(10.5  10  0.1 cm). Titanium (Ti) mesh electrode (10  10  0.1 cm) and the saturated calomel 

electrode (SCE) served as the counter and reference electrode, respectively.  
 

  

Figure 1. Glass cell containing Ti mesh counter and SCE reference electrodes used for 
determination of electroactive area of working electrodes (Al, Fe, G, Ti/RuO2) 

Cyclic voltammetry experiments were performed at different scanning rates, V = 10100 mV s-1 

in a potential window of ± 10 mV around the equilibrium potential (E0). Anodic (ia) and cathodic (ic) 

currents were obtained as electrochemical responses to the potential change. The capacitive 

current (icap) was calculated by means of equation (1), while Cdl value was calculated as the slope of 

linear relation obtained by presenting icap vs. V. The EA, is obtained by means of equation (2), where 

Cst is the normal capacitance taken as Cst = 60 F cm-2 for roughened electrodes 7. 

a c
cap

2

i i
i


  (1) 



F. Prieto-García et al. J. Electrochem. Sci. Eng. 7(2) (2017) 89-101 

doi:10.5599/jese.381 91 

dl

st

EA
c

c
   (2) 

Measurements of polarization curves 

With the polarization curves it is possible to determine the electrode of the highest oxidation 

capacity attained with consumption of the lowest energy. The potentioamperometric technique 

was explored using a sample of acid whey (30 mL) and geometrically smaller electrodes. The 

electrodes were submerged to a height of 2.0 cm and the exposed geometric areas were 6.96 cm2 

(Al), 8.78 cm2 (Fe), 4.65 cm2 (G) and 8.6 cm2 (Ti/RuO2). The real electrode areas were determined 

following the methodology described above. Three-electrode glass cell was used and shown in 

Figure 2a, where the working electrode is the G electrode, while Ti mesh and SCE served as the 

auxiliary and reference electrodes, respectively. Figure 2b shows a three-electrode cell containing 

30 mL of acid whey used for chronoamperometric experiments, performed by applying different 

overpotentials, η, defined by the equation (3) for 45 minutes. 

 
Figure 2. Three-electrode glass cell used for determination of electroactive area of small 

electrodes (G, Ti-mesh and SCE are the working, counter and reference electrodes) a). 
Electrolytic cell containing 30 mL of acid whey for polarization measurements  

(Al, Ti-plate and SCE are the working, counter and reference electrodes) b) 

Constant stirring is maintained during the test to obtain the current (i) in response. The current 

density (j) is calculated by the equation (4). 

= Eapplied - E0 (3) 

j = i / EA  (4) 

Results and discussion 

Determination of electroactive area (EA) of electrodes 

Cyclic voltammograms of Al, Fe, G and Ti/RuO2 electrodes in 0.1 M KCl recorded at different scan 

rates (v) are together with i vs. υ curves shown in Figures 36. Numerical data for icap determined 

by eq. (1) are collected in Table 1. Contrary to Figures 3 and 4 that showed ordinary capacitive 

current responses of G and Ti/RuO2 electrodes, in the case of Al and Fe electrodes presented in 

Figures 5 and 6, the tendency is quite different. Lack from usual linear icap vs. v response is 

particularly obvious for the Fe electrode and is probably due to the dissolution of electrode in acid 

medium.  

a) b)  



J. Electrochem. Sci. Eng. 7(2) (2017) 89-101 ELECTROCOAGULATION OF WHEY ACIDS 

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 E / V vs. SCE E / V vs. SCE 

Figure 3. Cyclic voltammograms of graphite electrode (G) in 0.1 M KCl, at different scanning 
rates (v = 0.01 to 0.10 V s-1) (A). icap vs. v (B) 

 
 E / V vs. SCE v / V s-1 

Figure 4. Cyclic voltammograms of Ti/RuO2 electrode in 0.1 M KCl at different scanning rates  
(v= 0.01 to 0.10 V s-1) (A). icap vs. v (B) 

 
 E / V vs. SCE v / V s-1 

Figure 5. Cyclic voltammograms of Al electrode in 0.1 M KCl at different scanning rates  
(v = 0.01 to 0.10 V s-1) (A). icap vs. v (B) 

The electroactive area (EA) of the working electrode represents the number of active sites where 

the electron transfer takes place and is usually estimated as the real electrode area (Areal) defined 

by eq. (2). EA can increase or decrease with respect to the geometric area, what is mainly due to 

the modification of the electro-active electrode surface. When an EC process is carried out, the 

anode (Al or Fe) undergoes oxidation reaction, which leads to the release of metal ions (sacrificial 

 

 

 

 

  

 

i 
/ 

A
 

i 
/ 

A
 

i 
/ 

A
 

i 
/ 

A
 

i 
/ 

A
 

i 
/ 

A
 



F. Prieto-García et al. J. Electrochem. Sci. Eng. 7(2) (2017) 89-101 

doi:10.5599/jese.381 93 

anode) and concomitant dissolution process 4,8-11. causing diminishing of the surface area. At the 

other hand, increase of the EA could also happen due to the porosity induced by the EC process. 

 

 
 E / V vs. SCE v / V s-1 

Figure 6. Cyclic voltammograms of Fe electrode in 0.1 M KCl at different scanning rates  
(v = 0.01 to 0.10 V s-1) (A). icap vs. v B) 

Table 1. Capacitive currents (icap) for different EC electrodes at different scanning rates v 

V / V s-1 
icap / A 

G Ti/RuO2 Al Fe 

0.01 0.00209 0.00229 0.00003 0.0134 

0.02 0.00318 0.00378 0.00005 0.0165 

0.03 0.00434 0.00573 0.00007 0.0222 

0.04 0.00538 0.00728 0.00009 0.0231 

0.05 0.00623 0.00874 0.00011 0.0240 

0.06 0.00718 0.01007 0.00013 0.0244 

0.07 0.00799 0.01121 0.00015 0.0245 

0.08 0.00899 0.01218 0.00017 0.0245 

0.09 0.0098 0.01308 0.00019 0.0242 

0.10 0.01055 0.01385 0.00021 0.0242 

 

Double-layer capacitance (Cdl) and EA values, calculated using data in Table 1 and eq. (2), are 

summarized in Table 2.  

Table 2. Real area (EA) and capacitance (Cdl) of different electrodes for the electrocoagulation process 

Electrodes Equation R2 Cdl / F EA, cm2 GA*, cm2 Roughness factor 

G y=0.0936x+0.0014 0.9967 0.0936 1,560 103.84 15.03 
Ti/RuO2 y=0.130x+0.0010 0.9821 0.130 2,167 107.05 20.24 

Al y=0.002x +10-5 1.0000 0.0020 33.3 104.02 0.32 
Fe y=0.101x +0.016 0.617 0.1010 1,689 105.02 16.1 

GA* - Geometric area 

It is obvious from Table 2 that Ti/RuO2 electrode showed the largest EA (2,167 cm2), what is due 

to the RuO2 metal oxide that generates micro, meso and macropores, and so greater surface 

roughness and higher capacitance (Cdl) values were obtained. At the same time, Al electrode showed 

the smallest EA (33.3 cm2) because it is a smooth and polished metal plate that exhibits the lowest 

Cdl among all electrodes. It has generally been stated that for cathodes, greater EA is generally 

i 
/ 

A
 i

 /
 A

 



J. Electrochem. Sci. Eng. 7(2) (2017) 89-101 ELECTROCOAGULATION OF WHEY ACIDS 

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beneficial. Data in Table 2 show that for Ti/RuO2 and G electrodes, EA are 2,167 cm2 and 1,560 cm2, 

respectively. This makes the Ti/RuO2 electrode to be better cathode under the perspective of 

electroactive areas. Also, regarding the electroactive area, the Fe electrode having EA of 1,689 cm2 

seems better than the Al electrode having 33.3 cm2. Although being indicative, the value of EA, 

however, is not a definitive factor for the choice of the most proper electrodes for EC. 

Choice of better arrangement of electrodes by means of polarization curves 

Aluminum electrode 

Chronoamperometric, i vs. t responses of the Al electrode in acid way sample recorded during 45 

min are presented in Figures 7 and 8. Similar behavior is observed at different potentials (Eapp) 

applied between 0.650 and 1,050 mV. As Eapp was increased, i was increased in the same way. 

However, at very high Eapp (850 and 1,050 mV) the decomposition of the medium is already 

occurring, which leads to unnecessary energy consumption. Figure 9 shows i vs. Eapp responses for 

the Al electrode (EA = 33.3 cm2) in the acid whey sample. It is obvious from Fig. 9 that the limiting 

current (il) where diffusional control begins is reached at about 400 mV vs. SCE and that diffusional 

currents are in a range of 0.039 and 0.042 A. Despite application of higher voltages, there are no 

greater transformations of the species present in the medium, up to the potential suitable for 

secondary reactions like the electrolysis of the water. Figure 10 shows the polarization curve,  

log j vs., of the Al electrode. In this graph, it is observed that the limiting current is reached by 

diffusional control at overpotential of 200 mV. This suggests that from the results obtained 

previously during the EC with a removal efficiency of 79 % in 8 h, the energy required can be reduced 

(by decreasing  from 1.74 to 0.2 V) to obtain the same removal efficiency and possible reduction 

of time. 

 
Time, s 

Figure 7. Chronoamperometric i vs. t responses of Al electrode in acid whey sample recorded 

during 45 minutes at Eapp between 650 mV and +1,050 mV 

 1 TIME, s 

i 
/ 

A
 



F. Prieto-García et al. J. Electrochem. Sci. Eng. 7(2) (2017) 89-101 

doi:10.5599/jese.381 95 

 
Time, s 

Figure 8. Chronoamperometric i vs. t responses of Al electrode recorded at  

Eapp between 650 mV and 550 mV (zoom of Fig. 7) 

 
E / mV 

Figure 9. i vs. Eapp of Al electrode in acid whey sample at Eapp between 650 mV and +650 mV 

 

Figure 10. log j vs. dependence of Al electrode in acid whey sample 

 1 
TIME, s 

 1 

 2 

-7

-6

-5

-4

-3

-2

-1

0

0 300 600 900 1200 1500 1800

 / mV 

 
lo

g
 (

j/
m

A
 c

m
-2

) 

i 
/ 

A
 

i 
/ 

A
 



J. Electrochem. Sci. Eng. 7(2) (2017) 89-101 ELECTROCOAGULATION OF WHEY ACIDS 

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Iron electrode  

The chronoamperometric, i vs. t curves of the Fe electrode in acid whey sample recorded during 

45 min are shown in Figures 11 and 12. Almost constant current values observed with time at each 

Eapp applied between 650 and 150 mV suggest that only capacitive currents are generated at the 

Fe electrode in contact with the acid whey solution. When applying Eapp between 0 to 100 mV, 

however, the first change in the oxidation state of Fe° to Fe2+ is observed with transfer of 2e coupled 

with the decomposition of the medium. At Eapp between 100 to 450 mV, a second change in current 

is observed due to the electrochemical oxidation of Fe2+ to Fe3+, so that the oxidation of iron is 

considered to occur in two stages (eqs. 5 and 6): 

Fe°  Fe2+ + 2e (5) 

Fe2+  Fe3+ + 1e (6) 

Finally, by applying Eapp higher than 450 mV the electrolysis of the medium that is decomposition 

of the whey begins, what is accompanied by the significant current increase with time. i vs. Eapp and 

log j vs.  dependences are presented in Figures 13 and 14. Here also, two different processes which 

are related to iron oxidation can be observed as in the chronoamperometry experiments. With these 

polarization curves it is verified that in the EC system, generation of Fe2+ or Fe3+ can be favored to 

improve the efficiency of the system in a shorter time and lower energy cost. 
 

 
Time, s 

Figure 11. Chronoamperometric i vs. t responses of Fe electrode in acid whey sample recorded 

during 45 minutes at Eapp between 1050 mV and +1050 mV 

The above statement can be based on the Pourbaix diagram for the thermodynamic states of the 

iron in aqueous solution, where when applying potentials within the range of 0.6 to 1.6 V vs. SCE, 

the oxidation process occurs and Fe2+ or Fe3+ ions are released depending on the pH of the solution. 

For acid conditions, both species are present and the process of corrosion is facilitated. It should be 

analyzed in more detail, however, which reaction would favor the EC process for the whey solution 

 1 

I, A 

i 
/ 

A
 



F. Prieto-García et al. J. Electrochem. Sci. Eng. 7(2) (2017) 89-101 

doi:10.5599/jese.381 97 

and formation of the iron oxy-hydroxides. Thus, one would be able to establish the optimum limiting 

current according to the limiting reagent that controls the reaction.  

 
Time, s 

Figure 12. Chronoamperometric i vs. t responses of Fe electrode at Eapp between 650 mV and 

450 mV (zoom of Fig. 11) 

 
E / mV vs. SCE 

Figure 13. i vs. Eapp of Fe electrode in acid whey sample at Eapp between 650 mV and 850 mV 

The bibliographical reports on the EC processes using iron electrodes are contradictory. Most EC 

studies have focused on the removal of contaminants by their co-precipitation with the solid(s) such 

are already formed precipitates of Fe(OH)2(s) and Fe(OH)3(s). Also, the reactions reported in the 

literature showed a certain ambiguity in the proposed mechanisms. Some studies 13-15 have 

reported that the oxidation of iron Fe0 to Fe2+ occurs in an electrolytic form and produces insoluble 

Fe(OH)2(s) compounds by hydrolysis. Other authors 16 pointed to the formation of Fe(OH)2(s) 

without giving details of how it occurs. Several studies 8,17,18 reported formation of Fe2+ at the 

anode that is followed by oxidation to Fe3+ due to dissolved oxygen (DO) and rapid formation of 

Fe(OH)3(s). The third mechanism reported 7,8,10 involves the single and fast electrolytic oxidation 

 1 

I, A 

 1 

E/mV vs. SCE 

i 
/ 

A
 

i 
/ 

A
 



J. Electrochem. Sci. Eng. 7(2) (2017) 89-101 ELECTROCOAGULATION OF WHEY ACIDS 

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step of Fe0 to Fe3+, followed by hydrolysis to produce Fe(OH)3(s). Finally, some studies 16,19,20 

have reported formation of Fe(OH)3(s) as the final product during EC without specifying the 

reactions involved. According to 21, the third mechanism is questionable. These authors pointed 

out dependence of the kinetics of these reactions on the pH of the medium. They reported that at 

pH 7.5, approximately 80% of the Fe2+ initially formed is oxidized to Fe3+ in less than 10 minutes, 

while at pH 6.5, the same oxidation process takes about 300 minutes (5 h). The rapid increase in 

Fe2+ oxidation rate with pH increase is consistent with other reports in the literature, where based 

on equations (7) and (8), it was shown that increase of pH increases the oxidation rate of Fe2+ for 

about 100 times 2224. 

 
 / mV 

Figure 14. Log j vs. dependence of Fe electrode in acid whey sample.  

4Fe2+ + O2 + 2H2O + 8OH ↔ 4Fe(OH)3(s) (7) 

d[Fe2+]/dt = k[Fe2+] PO2 [OH
-]2 (8) 

In eq. (8), k is the rate constant, PO2 is the oxygen partial pressure, while the molar concentrations 

of present species are represented in the brackets.  

A slight increase in the concentration of OH ions as observed during EC and corroborated with 

the increase of pH, has resulted in a greater concentration of the Fe2+ species forming Fe3+ by 

subsequent oxidation and Fe(OH)3(s) by precipitation. Since OH ions are consumed during the 

hydrolysis of Fe3+, pH in the electrolytic cell decreases in a subsequent step that does not occur 

immediately. By the time elapsed between the production of Fe2+ and its oxidation to Fe3+ by the 

oxygen dissolved in the medium, a reaction that is much slower has been indicated.  

Graphite electrode  

In Figures 15 and 16, the chronoamperometric i vs. t responses of the G electrode recorded 

through 45 min are presented, showing the same behavior at different Eapp applied. As Eapp 

increases, i increased in the same way. At very negative Eapp (1050 mV), however, it can be 

observed that the decomposition of the medium occurs. By presenting log j vs. dependence, Fig. 17 

suggests that the limiting current (il) is occurring at overpotential of 500 mV, where diffusional 

control begins. 

 1 

 2 

 3 

 4 

 5 

 6 

 7 

 8 

 9 

 10 

lo
g

 (
 j

 /
m

A
 c

m
-2

) 



F. Prieto-García et al. J. Electrochem. Sci. Eng. 7(2) (2017) 89-101 

doi:10.5599/jese.381 99 

 
Time, s 

Figure 15. Chronoamperometric i vs. t responses of G electrode in acid whey sample recorded 

during 45 min at Eapp between 70 mV and 1050 mV. 

 
                        Time, s 

Figure 16. Chronoamperometric i vs. t responses of the G electrode at Eapp between 12 mV and 

250 mV (zoom of Fig. 15) 

 
 / mV 

Figure 17. log j vs.  dependence of G electrode in acid whey sample. 

i 
/ 

A
 

i 
/ 

A
 

lo
g

 (
j 

/m
A

 c
m

-2
) 



J. Electrochem. Sci. Eng. 7(2) (2017) 89-101 ELECTROCOAGULATION OF WHEY ACIDS 

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Selection of the anodic material for the electrocoagulation process. 

With the electrochemical information obtained so far, the Tafel slopes for the electrodes acting 

as sacrificial anodes (Al and Fe) are compared in Figure 18.  
To select the best electrode, the largest slope must be taken into account. The results for Fe and 

Al electrodes are different, for the Al electrode, b = -54.55 mV dec-1 and for Fe, b = -109.98 mV dec-1. 
In this respect, it is possible to define that the Fe electrode is considered the most effective. Figure 
19 shows a better separation of the precipitate and purified liquid more transparent with the use of 
the Fe electrode (Figure 19 a).  

 

 
 

log (j / A cm-2) 

Figure 18. Tafel slopes of Fe and Al electrodes in acid whey samples 

 

 

Figure 19. Purification kinetics of acid whey with Fe (a) and Al (b) electrodes 

Conclusions  

The iron electrode proved to be better anode than Al for the EC process. This is due to its stable 

thermodynamic behavior in the range of applied overpotentials, which translates into a greater 

transfer of charge in a shorter time. By correlating these results with the results obtained during the 

preliminary tests, it can be confirmed that the Fe electrode is better than the Al electrode. With the 

Fe electrode, greater removals (79 are obtained in less time (8 h)). On the other hand, with the Al 

 1 

 2 

 3 

log (i/A cm
-2

) 

 


/m
V

 v
s-

 S
C

E
 

 

 
 

 

a) 

b) 


 /

 m
V

 v
s.

 S
C

E
 



F. Prieto-García et al. J. Electrochem. Sci. Eng. 7(2) (2017) 89-101 

doi:10.5599/jese.381 101 

electrode, the results of macroelectrolysis required more time (24 h) to achieve an efficiency of 49 

%. Based on the determinations of the electroactive area, the Ti/RuO2 electrode (2,167 cm2) proved 

to be a better cathode than the graphite (1,560 cm2). 

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