Bioremediation of oil and heavy metal contaminated soil in construction sites: a case study of using bioventing-biosparging and phytoextraction techniques

TL;DR

This study evaluates bioremediation techniques like bioventing-biosparging and phytoextraction for cleaning oil and heavy metal contaminated soils at a construction site, highlighting the impact of cement components on remediation efficiency.

Contribution

It provides new insights into how cementitious materials affect the performance of bioremediation methods in contaminated construction soils.

Findings

Cement presence reduces degradation of BTEX and PAHs in deep soil layers.

Cement stabilizes surficial soil, increasing Pb removal efficiency.

Bioremediation performance is significantly influenced by cement components.

Abstract

This paper studies the bioremediation techniques utilized for degrading soil pollutants in a construction site located in Iran. The activities in a construction site, located in Garmdareh, Karaj, polluted the soil environment with a large amount of contaminants among which BTEX, PAHs and heavy metals are considered to be the most important components. Employing conventional physicochemical techniques for remediation of such a polluted soil is both technically and economically challenging. Bioremediation, which involves taking advantage of the microorganisms for the removal of pollutants, is the most promising technology which is both relatively efficient and cost-effective. In this study, the coupled bioventing-biosparging technique and the phytoextraction process were utilized to remediate the deep and shallow layers of the polluted environment, respectively. However, the widespread presence of the cement components in the site influenced the performance of bioremediation techniques. The results of this study indicated that the cement- polluted soil lowered the degradation rate of both BTEX (Ethylbenzene) and PAH (Pyrene) pollutants within deep layers. Conversely, the degradation rate of Pb was increased in phytoextraction process due to proper stabilization of the surficial soil in presence of cement components. This study provides a critical view on the limitations and influential parameters of function-directed soil remediation techniques dealing with the presence of cementitious materials in construction sites.