The technique of arsenic elimination from contaminated soil with enhanced conditions by electro-kinetic remediation

Remediation of arsenic-contaminated soil by the technique of electro-kinetic using various enhanced conditions is the thrust of this study. Many tests were performed with different operating conditions, such as the electrodes solution (tap water) with a variable pH at (2, 5, and 8). Cyclodextrin (10% hydroxypropyl-beta-cyclodextrin, or HPCD) has been used as an activating agent that helps enhance this process of soil arsenic clean-up. Agricultural wastes (pomegranate peels) were used after treating them as an adsorbent to impede the return of pollutants to the soil as a result of reverse osmosis. The results obtained after the remediation's completion indicated that the best elimination capacity was 72% at a pH of 2. This indicates that the elimination capacity increases with the decreasing pH of the electrodes solution. Mixing the HPCD solution with soil as an enhanced solution increased the solubility and desorption of arsenic from the soil. Then, arsenic-containing HPCD micelles readily moved to the cathode electrode by electro-osmotic flow, and the elimination capacity increased (84%). It was concluded that pomegranate peels are a good adsorbent for arsenic returning to the soil during the treatment process as a result of reverse osmosis. Hence, the application of this material in this research gave a perfect impression of its use as an inexpensive, environmentally friendly adsorbent and an alternative to commercial absorbents.

Automated summary

The study focuses on remediating arsenic-contaminated soil using electro-kinetic techniques with various enhanced conditions. Tests were conducted with different operating conditions and it was found that decreasing the pH of the electrodes solution increased the elimination capacity of arsenic. Mixing a cyclodextrin solution with the soil enhanced the solubility and desorption of arsenic, resulting in a higher elimination capacity. Pomegranate peels were found to be an effective adsorbent for preventing arsenic from returning to the soil during treatment.