부산대학교 도서관

Soils contaminated with potentially toxic elements (PTEs) may face serious environmental problems and pose health risks. In this study, the potential feasibility of industrial and agricultural by-products as low-cost green stabilization materials for copper (Cu), chromium (Cr(VI)) and lead (Pb) polluted soil was investigated. The new green compound material SS ∼ BM ∼ PRP was prepared by ball milling with steel slag (SS), bone meal (BM), and phosphate rock powder (PRP) which had an excellent stabilization effect on contaminated soil. Under 20% SS ∼ BM ∼ PRP addition into the soil, the toxicity characteristic leaching concentrations of Cu, Cr(VI) and Pb were reduced by 87.5%, 80.9% and 99.8%, respectively, and the phytoavailability and bioaccessibility of PTEs were reduced by more than 55% and 23%. The freezing-thawing cycle significantly increased the activity of heavy metals, and the particle size became smaller due to the fragmentation of the soil aggregates while SS ∼ BM ∼ PRP could form calcium silicate hydrate by hydrolysis to cement the soil particles, which inhibited the release of PTEs. Different characterizations indicated that the stabilization mechanisms mainly involved ion exchange, precipitation, adsorption and redox reaction. Overall, the results obtained suggest that the SS ∼ BM ∼ PRP is a green, efficient and durable material for remediation of various heavy metal polluted soils in cold regions and a potential method for co-processing and reusing industrial and agricultural wastes. [Display omitted] • A compound material of SS ∼ BM ∼ PRP (3:1:5) was obtained to stabilize Cu, Cr(VI) and Pb. • TCLP leaching of Cu, Cr(VI) and Pb were reduced by over 80% at 20% SS ∼ BM ∼ PRP dose. • The SS ∼ BM ∼ PRP could resist the adverse effects of freezing-thawing cycles on soil. • Potentially toxic elements transformed from labile to relatively stable form. • Ion exchange, chemical- and co-precipitation, redox and adsorption were involved. [ABSTRACT FROM AUTHOR]