Electrokinetic Remediation Technique: An Integrated Approach to Finding New Strategies for Restoration of Saline Soil and to Control Seawater Intrusion

Hamdan, Shadi H.; Molelekwa, Gomotsegang Fred; Bruggen, Bart Van der

doi:10.1002/celc.201402071

Cited by 30 publications

(18 citation statements)

References 146 publications

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“…However, the main aim is to develop a technology capable of removing the pollutant and allowing the recovery of the soil [2,[11][12][13]. Within the technologies capable of confining pollution, electrokinetic fences (EKF) is perhaps one of the most interesting, at least from a theoretical point of view [11,14].…”

Section: Introductionmentioning

confidence: 99%

Removal of oxyfluorfen from spiked soils using electrokinetic fences

Risco

Rubí-Juárez

Rodrigo

et al. 2016

Separation and Purification Technology

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In this work, an accidental spill of Fluoxyl (commercial herbicide containing oxyfluorfen) is simulated in a pilot plant with a soil volume of 70x50x50 cm 3. The transport of Fluoxyl obtained by the free diffusion of pollution and under the application of the electrokinetic fences (EKF) technology are compared in a 34-day treatment. In addition, the temperature, conductivity, and pH are monitored daily. At the end of the experiment, a post-mortem analysis is carried out in order to obtain a 3-D distribution map of the pollutant. The results show that EKF is a good technology to remove oxyfluorfen from the soil without excavation because it is able to attain a fast transfer of oxyfluorfen to the flushing fluid used. After 34 days, the decrease in the concentration of oxyfluofen in the

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Section: Introductionmentioning

confidence: 99%

Removal of oxyfluorfen from spiked soils using electrokinetic fences

Risco

Rubí-Juárez

Rodrigo

et al. 2016

Separation and Purification Technology

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“…Electrochemical technologies, for instance MFC and the electrokinetic technique, are promising remediation approaches for soil/sediment contamination [ 11 , 12 ]. The performance of remediation is mainly determined by the system resistance [ 5 , 13 ].…”

Section: Introductionmentioning

confidence: 99%

In Situ Representation of Soil/Sediment Conductivity Using Electrochemical Impedance Spectroscopy

Wang

Zhao

et al. 2016

Sensors

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The electrical conductivity (EC) of soil is generally measured after soil extraction, so this method cannot represent the in situ EC of soil (e.g., EC of soils with different moisture contents) and therefore lacks comparability in some cases. Using a resistance measurement apparatus converted from a configuration of soil microbial fuel cell, the in situ soil EC was evaluated according to the Ohmic resistance (Rs) measured using electrochemical impedance spectroscopy. The EC of soils with moisture content from 9.1% to 37.5% was calculated according to Rs. A significant positive correlation (R2 = 0.896, p < 0.01) between the soil EC and the moisture content was observed, which demonstrated the feasibility of the approach. This new method can not only represent the actual soil EC, but also does not need any pretreatment. Thus it may be used widely in the measurement of the EC for soils and sediments.

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“…Solvent extraction, chemical precipitation and flocculation, and electrochemical deposition have been typically employed to recover Sn, Cu and Fe from stripping solutions generated from PrCB manufacturing ,,. However, the entire treatment process required pH adjustments by the addition of caustic (0.1–1.0 M), and the operational costs associated with continuous chemical addition or electricity consumption were high.…”

Section: Introductionmentioning

confidence: 99%

Efficient In Situ Utilization of Caustic for Sequential Recovery and Separation of Sn, Fe, and Cu in Microbial Fuel Cells

et al. 2018

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A novel strategy to sequentially recover and separate Sn(II), Fe(II) and Cu(II) from a synthetic wastewater from printed circuit board (PrCB) manufacturing in a single microbial fuel cell (MFCSn)‐MFCFe‐MFCCu process was achieved, where in‐situ produced caustic was primarily utilized for Sn precipitation (MFCSn) and then secondly used for Fe deposition (MFCFe) and anaerobic Cu(II) reduction in the final MFCCu. An external resistance of 1000 Ω in the MFCSn and MFCFe, and a 10 Ω resistor in the MFCCu achieved predominant recovery of Sn (MFCSn: 80.8±0.8 %), Fe (MFCFe: 59.1±0.8 %), and Cu (MFCCu: 68.2±1.8 %) in the three MFCs, with separation factors of 32.1±1.6 for Sn (MFCSn) and 7.5±1.8 for Fe (MFCFe), and complete recovery of Cu (MFCCu, 42‐mesh cathodes). The metal concentrations in the final effluent were below national discharge limits (Sn, 2.0 mg/L; Fe, 5.0 mg/L; Cu, 0.2 mg/L). The metal recoveries ranged from 2.6 (Sn, MFCSn)–12.0 (Cu, MFCCu), and the separation factors were 8.4 (Sn, MFCSn)–∞ (Cu, MFCCu) times those of the open circuit controls. Cathodes with 120‐mesh size of stainless steel mesh produced lower metal recoveries [33.7 % (Sn, MFCSn) and 27.0 % (Fe, MFCFe) decrease] and separation factors than MFCs with 42‐mesh cathodes. This study provides a viable approach for efficiently recovering and separating Sn, Fe and Cu from stripping solutions produced in PrCB manufacturing, with simultaneous power production.

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Electrokinetic Remediation Technique: An Integrated Approach to Finding New Strategies for Restoration of Saline Soil and to Control Seawater Intrusion

Cited by 30 publications

References 146 publications

Removal of oxyfluorfen from spiked soils using electrokinetic fences

Removal of oxyfluorfen from spiked soils using electrokinetic fences

In Situ Representation of Soil/Sediment Conductivity Using Electrochemical Impedance Spectroscopy

Efficient In Situ Utilization of Caustic for Sequential Recovery and Separation of Sn, Fe, and Cu in Microbial Fuel Cells

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