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 CCHHEEMMIICCAALL  EENNGGIINNEEEERRIINNGG  TTRRAANNSSAACCTTIIOONNSS  
 

VOL. 41, 2014 

A publication of 

The Italian Association 
of Chemical Engineering 

www.aidic.it/cet 
Guest Editors: Simonetta Palmas, Michele Mascia, Annalisa Vacca
Copyright © 2014, AIDIC Servizi S.r.l., 
ISBN 978-88-95608-32-7; ISSN 2283-9216                                                                                     
 

Application of Electrochemical Technologies to Treat 
Polluted Soil by Diesel 

Elisama Vieira dos Santos, Mariana Oliveira Medeiros, Aecia S. Dantas dos 
Anjos, Carlos A. Martínez-Huitle*, Djalma Ribeiro da Silva  

Federal University of Rio Grande do Norte, Institute of Chemistry, Lagoa Nova CEP 59078-970 - Natal, RN, Brazil  
carlosmh@quimica.ufrn.br 

This study reports on the effects of electrokinetic remediation to remove organic contaminants and heavy 
metals from contaminated soil by using different electrolytes. Ti/Ru0.3Ti0.7O2 electrode with an area of 50 
cm2 was used as anode, while as cathode a grid of Ti. Different electrokinetic total petroleum hydrocarbon 
(TPH) removal efficiencies were achieved, depending on the supporting electrolyte used, as follows: 
Na2SO4 (96.46%), citric acid (81.36 %) and NaOH (68.03 %) during the first 15 days of electrochemical 
treatment. The results described here suggest that the application of electrokinetics can be a promising 
soil remediation technology; if the soil parameters (electric current and electrolyte) are appropriately 
controlled based on the understanding of interaction between organic pollutants and soil. The main 
removal mechanism of diesel from soil was electroosmosis. On the other hand, wastewater collected from 
the electrokinetic remediation process, which was polluted with TPH, it was successfully oxidized by using 
electrochemical oxidation treatment. The level of degradation achieved was considerably high (>70%) in 
all cases, after 10 h of electrolysis. 
 

1. Introduction 
The Electrokinetic (EK) process is promising for organic and metals removal from soil. Several research 
groups have studied on organic movement to and retention near the anode by the EK technique (Reddy, 
and Saichek, 2004; Chil-Sung et al., 2010; Alcántara et al., 2010; Reddy, 2010; Byung-Gon et al., 2011; 
Méndez et al., 2012; Cameselle and Reddy, 2012; Pazos et al., 2013). Recently, the application of 
electrokinetic technology to organic is attracting interest from the scientific community to removal pyreno, 
total petroleum hidrocarbon (TPH), heavy metals, naphthalene (Reddy, 2010; Ferri et al., 2009). The 
remediation can be conducted in situ to treat contaminants in low-permeability zones by applying a direct 
current between electrodes placed in the remediation site, achieving high efficiency on removal. The 
transport phenomena of contaminants in the soil can be briefly described as follows: electromigration, 
electroosmosis and electrophoresis. Electromigration is the transport of ions and ion complexes toward the 
electrode of opposite charge; Electroosmosis is defined as the movement of soil moisture or groundwater, 
which generally takes place from the anode to the cathode and is due to the existence of a space-charge 
on the solution side of the particle/solution interface. Its migration toward the cathode causes solution 
displacement too, thus generating a cathode-directed electroosmotic flow. Electrophoresis, as the 
movement of charged particles under an electric gradient, contaminants bound to mobile particulate matter 
can be transported in this manner as well (Ferri et al., 2009; Pazos et al., 2012; Bustos, 2012). These 
mechanisms facilitate decontamination by initiating physical, chemical or hydrological changes such as 
desorption, adsorption, oxidation, gas generation, dissolution, precipitation, reduction, ion exchange, pH 
gradient formation, destruction of soil particle active sites (Pazos et al., 2012; Bustos, 2012).  
Several studies have also been assessed the effect electrolytes such as NaCl, KCl, NH4, CH3COONa, 
Na2SO4, Na3PO4, MnO4

-, H2O2, CaCl2 and citric acid on the electrokinetic and rheological behaviours of 
soil obtaining different removal organic matter efficiencies (Ferri et al., 2009; Pazos et al., 2012; Bustos, 

                                                                                                                                                      
 
 
 
 

          DOI: 10.3303/CET1441027 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 

Please cite this article as: Vieira Dos Santos E., Oliveira Medeiros M., Dantas Dos Anjos A.S., Martinez-Huitle C.A., Ribeiro Da Silva D., 
2014, Application of electrochemical technologies to treat polluted soil by diesel, Chemical Engineering Transactions, 41, 157-162  
 DOI: 10.3303/CET1441027

157



2012). It has been demonstrated to be successful and cost-effective in removing wide variety of pollutants 
such as heavy metals and organic contaminants in many bench- and field-scale studies.  
EK remediation has also been proposed as an innovative technology for remediation of saturated or 
unsaturated soils, Few studies have investigated the removal of diesel from contaminated soil by 
electrokinetically enhanced oxidation with the presence of both H2O2 and Fe3O4 (iron electrode corrosion), 
achieving higher TPH-D removal efficiency (97%) compared to the efficiencies observed from EK (55%) or 
Fenton oxidation (27%) alone. To improve of individual remediation techniques and to achieve better 
organic compounds removal efficiencies have been proposed; various combinations of physical, chemical 
and biological, as a  physical-chemical treatment, physical-biological treatment, biological-chemical, 
physical-chemical-biological treatments to treat diesel contaminants in soil (Ferri et al., 2009; Reddy, 2010; 
Pazos et al., 2012; Bustos, 2012).  
The objective of this work is to test a combined process of electrokinetic remediation for diesel remediation 
from soil contaminated followed by electrochemical oxidation to remove organic pollutants from 
wastewater produced. The influence of operating parameters that play an important role in the 
electrokinetic process, such as effect of the electrolyte and applied current density were investigated 
 

2. Materials and Methods 

2.1 Preparation of soil samples 
Sample of soil was collected from Northeast Brazilian gas & oil station. The soil was spiked with 
commercial diesel fuel by introducing a pollutant solution of diesel fuel (10 mL) in n-hexane (20 mL) into 
soil samples (1 Kg) to obtain a representative contaminant concentration for soil. About 950 g of soil 
material were treated in each test. The mixture was easily stirred and blended homogeneously. The 
mixture was kept at room temperature (25°). All physical parameters of soil were determined according to 
the ASTM standard methods and are listed in Table 1. The soil pH and electrical conductivity were 
determined by a pH meter and a conductivity-meter respectively, with a ratio of 1:2.5 soil to water. The 
organic carbon and cation exchange capacity (CEC) were analysed by dichromate oxidation method and 
ammonium acetate extraction method, respectively. Afterwards, a representative sample (approx. 50 g) of 
the mixture was taken for initial analysis of diesel concentration. X-ray diffraction analysis was performed. 
Table 1 shows the characteristic of the soil used. 
 

2.2 Analysis of organic matter removal from soil and Diesel removal 
During EK process, organic matter removal from soil was monitored in terms of TOC removal in three soil 
sections (near to cathodic, central and near to anodic section). Also, Diesel concentration was measured 
as total petroleum hydrocarbons (TPH) using 10 g of sample treated in order to evaluate the elimination of 
TPH in the treated soil. The sample was mixed with n-hexane in a Soxhlet extractor for 6 h and 10 g of soil 
were mixed with 100 mL of n-hexane in a separate funnel. The superior phase was mixed with internal 
standard and analysed by gas chromatography. The HP-5 capillary column was used with helium carrier 
gas at a flow rate of 1 mL min

-1 and air at 400 mL min-1. The temperature program used was of 50 °C min-
1, after 8 °C min-1, and 320 °C for 10 min-1. The removal efficiency was calculated according to Eq.(1): 

            100 x 
C

C - C
  (% ) Removal

i

fi=                                                                                       (1) 

where Ci is the initial concentration of TPH in the soil and Cf is the final concentration of TPH in the treated 
soil. 
 

2.3 Electrokinetic cell 
The experiments were performed in a rectangular acrylic cell showed in Fig.1. The sample soil was 
introduced in the central compartment, in a rectangular system of 30 cm of length × 10 cm of width × 10 
cm of height. Two electrode chambers, with a working volume of 0.5 L, were placed at the lateral positions 
of the electrokinetic cell and it was isolated from the test soil by means of filter paper. Ti/Ru0.3Ti0.7O2 
electrodes were used as cathode and anode, with an area of 50 cm2, each one of them. The electrode 
chambers were filled with a solution of Na2SO4 0.1 M, NaOH 0.1 M and citric acid 0.1 M for each one of the 
experiments. A current density of 2 mA cm-2 was applied for 15 days in all experiments. Electrical potential 
and pH (in the electrode compartments) were periodically monitored, during the experimental tests. Table 
2 shows a summary of the experiments carried out. 
 

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2.4 Electrochemical oxidation experiments 
 
Bulk oxidations were performed in undivided electrochemical cell, the reaction compartment having a 
capacity of 1 L, and the solution was stirred by a magnetic stirrer. The electrolytic solution (effluent formed 
after electrokinetic treatment of soil) was stored in the electrochemical batch cell for treating 0.5 L. The 
oxidation experiments of solution were performed under galvanostatic conditions using a power supply 
MINIPA-3305M at 25 °C. The cell contained a Ti/Ru0.3Ti0.7O2 electrode as anode with 50 cm

2 of area. A 
current density of 20 mA cm-2 was applied during 10 h in all experiments. 

3. Results and Discussion 

3.1 Efficiency carbon organic total removal and electrical power consumption 
EK experiments were performed using Ti/Ru0.3Ti0.7O2 and Ti as anode and cathode, respectively, by 
applying 2 mA cm-2. During EK process, pH, conductivity and TOC removal were monitored in three soil 
sections (near to cathodic, central and near to anodic section). After EKR process, hydrocarbon content 
was also evaluated in the same three soil sections. Results in Fig. 1a clearly show that the initial TOC 
decreases as a function of time, obtaining different efficiencies depending on the electrokinetic cell 
sections: 48.11%; 48.51% and 73.14% on anodic, central and cathodic section for NaOH 0.1 M. The 
organic matter was easily transported via electroosmoic flow. This behaviour confirms the migration of 
organic pollutants (Ferri et al., 2009; Reddy, 2010; Pazos et al., 2012; Bustos, 2012) from different 
sections of soil to solutions reservoirs (anodic and cathodic solutions). In the case of Na2SO4, TOC 
decreases as a function of time in all electrokinetic cell sections removing 83.35%, 71.49% and 80.83%, at 
cathodic, central and anodic section, respectively (Fig. 1b). On the other hand, when citric acid was 
employed, TOC decay was around 43.35%, 73.49% and 42.83%, at cathodic, central and anodic section, 
respectively (Fig. 1c). These figures indicate that the Na2SO4 favours the elimination of organic matter 
from all sections in the polluted soil.  
 

 
 

Figure 1. TOC removal during EK process in three soil sections using as supporting electrolyte (a) NaOH, 
Na2SO4 and (c) citric acid by applying 2.0 mA cm

−2 for 15 days. Anode was Ti/Ru0.3Ti0.7O2 and as cathode, 
titanium (Ti).  

159



 
On the other hand, considering the electrical potential measured during the EK experiments, energy 
consumption was estimated. A total consumption of 121.21 kWh m-3 was spent after 15 days of EK 
treatment when NaOH was used as supporting electrolyte. Whereas, 111.16 kWh m-3 was necessary to 
obtain modest TOC decays when citric acid was employed. Conversely, lower energy consumption was 
employed when Na2SO4 was employed about 44.83 kWh m

-3. 
Fig. 2 shows the variation of pH, as a function of time, in the proximity of anode compartment, cathode 
reservoir and middle section using NaOH, Na2SO4 and citric acid as supporting electrolytes, for removing 
organics. When the electric potential is applied, the electrolysis reactions occur in the electrodes, 
producing H+ and OH− ions at the anode and cathode reservoirs, respectively. The initial pH of the soil-
Na2SO4 (middle section) was around 6.1 and it decreases to 4.1 during EKR tests, at anodic and middle 
sections; while at cathodic reservoir, pH increased considerably to around 10.5. Using  NaOH 0.1 M, initial 
pH was around 8.90, after that, it decreases up to 6.1, at anodic and middle sections; while pH around 12 
was attained after 15 days of treatment at cathodic section. Similar behaviour was observed at all sections 
when citric acid was used (Fig. 2c). A key feature of electrokinetic experiments is the electrolysis of water 
at the electrodes, resulting in the generation of acid and base at the anode and cathode respectively (Ferri 
et al., 2009; Reddy, 2010; Pazos et al., 2012; Bustos, 2012). The electrolytic reduction of water at the 
cathode causes H2 evolution and oxidation at the anode causes O2 evolution. An alkaline zone surrounds 
the cathode and an acidic zone is created at the anode:  
At the cathode: 4H2O + 4e

- →2H2(g) + 4OH
-    

At the anode: 2H2O →O2(g) + 4H+ + 4e-    
The pH is reduced not only the high concentration of H+, but also in a secondary manner by the release of 
Al3+ due to kaolinite dissolution (composition of soil) (Ferri et al., 2009; Reddy, 2010; Pazos et al., 2012; 
Bustos, 2012). The reduction of water molecules at the cathode leads H2 generation and increasing pH. 
Therefore, these reactions cause an acidic solution to be generated at the anode and an alkaline solution 
to be generated at the cathode. The electrolysis of water affects the remediation process because the ionic 
products may electromigrate and be transported by electro-osmosis towards the opposite charged 
electrode location. 
 

 
  

Figure 2. pH variation, as a function of time, during electrokinetic tests at different supporting electrolytes: 
(a) NaOH (b) Na2SO4 and (c) citric acid.  

160



Thus, an acidic front of solution may move from the anode towards the cathode and an alkaline front of 
solution may move from the cathode towards the anode. However, the pH will not increase directly to 12 
owing to interaction of OH- with residual H+ on the cathode surface (Ferri et al., 2009; Reddy, 2010; Pazos 
et al., 2012; Bustos, 2012).  
H+ + e- → ½ H2     
 
During the electrokinetic remediation, operating acidic and alkaline fronts migrate toward the opposing 
electrodes and interact approximately with a ¼ of the distance from the cathode to form a zone of abrupt 
pH change. The movement of these fronts is irregular, and the advection H+ front depends on 
electromigration, eletroosmosis, and diffusion mechanisms. Progress is hindered by high soil buffering 
capacity as a result of substitution with adsorbed cations (Pazos et al., 2012; Bustos, 2012). At the 
cathode zone OH- front advection is affected by upstream electromigration and the progress of OH- ions is 
hindered by electroosmosis. As shown Fig. 2a, the outlet catholyte pH increased continuously due to the 
basic front reaching the cathode and neutralizing the high pH. When NaOH was used, the soil pH may 
reduce the electroosmotic flow rate by causing the soil minerals to process a more positive surface charge 
and zeta potential, the flow velocity towards the cathode should have decreased over time (Pazos et al., 
2012; Bustos, 2012). Fig 2b shown citric acid the soil pH tended to increase near cathode little in the 
treatments and decreased little anode, this effect can be attributed to the impact of the electro-osmotic 
flow. This flow has an acidic pH below 4, and can react with the soil to release ions and increase the 
electrical conductivity (Bustos, 2012).  
 

3.2 Concentration of TPH in soil  
The initial concentration of TPH in the soil was found to be 9094.06 mg/Kg. Fig. 3 shows the TPH removal 
efficiency, in terms of percentage, as a function of supporting eletrolyte used (NaOH, citric acid and 
Na2SO4). There was a pattern of slight increase in the removal efficiency of TPH from cathodic to anodic 
section, indicating that the oil was removed mainly by electroosmosis flow. Analysing the figures reported, 
Na2SO4 is the most efficient supporting electrolyte because higher TPH elimination was achieved, more 
than 90%. The order of TPH removal efficiency is Na2SO4 (96.46%) > citric acid (81.36 %) and NaOH 
(68.03 %) during 15 of EK treatment. The registered electro-osmotic flow, approximately 42 mL d-1; 56 mL 
d-1 and 64 mL d-1 for NaOH, citric acid and Na2SO4 confirm the results obtained for %THP elimination.  
 

 
 

Figure 3. TPH removal efficiency using different supporting electrolytes in EK treatment.  

3.3 Electrochemical oxidation 
Bulk oxidations were performed in undivided electrochemical cell, the reaction compartment having a 
capacity of 1 L, and the solution was stirred by a magnetic stirrer. The experiments were conducted at 
25ºC by applying 20 mA cm-2 using Ti/Ru0.3Ti0.7O2 electrode. Fig. 4 shows the TOC decays, as a function 
of time, for the wastewater generated after EK treatment. TOC measurements confirm the elimination of 
organic matter accumulated in the reservoirs solutions after EK treatment. As can be observed from Fig. 4, 
more than 90% of organic materr dissolved was removed after 10 h of electrolysis. This results clearly 
demonstrated that the wastewater produced after EK treatment could be treated by using electrochemical 
oxidation process. In this context, two electrochemical technologies could be integrated in order to 
decrease the time of treatment, and consequently, decreasing the energy costs. The elimination of 

161



dissolved organic pollutants is due to the fact that OH radicals are produced at anode surface, favoring the 
electrochemical oxidation of them. However, this electrode is considered an active anode, limiting the 
efficiency on the removal. This limitation could be avoided when a non-active anode is used, for this 
reason, it is a new objective of our research.  Also, the formation of superior metal oxide at this electrode 
material decreases the efficiency of the electrochemical oxidation process at solution of NaOH. 
 

 

Figure 4. Electrochemical degradation of wastewater produced after EK treatment. Anode was 
Ti/Ru0.3Ti0.7O2 by applying 20 mA cm

-2. 

4. Conclusions 
The organic matter was eliminated from polluted soil due to the electromigration and electroosmotic flows, 
removing more than 80% of organic compounds using Na2SO4  0.1 M and 68% employing NaOH 0.1 M 
after 15 days. The soil pH variation is observed due to the buffering capacity of soil as well as the 
production of H+ and OH- at the electrocatalytic materials used. On the other hand, the liquid collected 
from the electrokinetic remediation process; it was successfully oxidized by using the electrochemical 
treatment (electrooxidation), verifying the applicability of combination of two electrochemical technologies. 

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