Heavy metals removal in a graphene engineered concrete-based filter column

Abstract

In this study, crushed aggregate surfaces were coated with reduced graphene oxide (RGO) using a chitosan-derived solution and included in porous concrete-based filter column samples to improve heavy metal removal. The RGO coating strengthened the aggregate and cement interfaces, thus improving the compressive strength of these samples by up to 18 %. The removal of lead and copper in samples containing RGO coated aggregate (GCA) operated with a minimum hydraulic load was found to be 97 % and 92 %. Increasing the hydraulic load reduced this heavy metal removal, but the presence of GCA increased the active sites for heavy metal ions to immobilize, leading to improved copper removal under such operating conditions. Calcium ions from the cement hydrates were found to leach from the concrete matrices during such a wastewater passage. This leaching of calcium ions was determined to be relatively lesser in RGO decorated concrete samples, pointing out the positive effects of GCA on the resistance of the concrete matrices to aggressive chemicals. Clay particles containing highly turbid water were also passed through these concrete samples to examine the effects on the infiltration rate. Clay particles were found to clog pores, marginally reducing the infiltration rate. Concrete-based water filters are easy to operate and have low maintenance requirements, and industries responsible for heavy metal pollution in aquatic environments can widely adopt them instead of complex treatment methods.