Immobilization of mercury by nano-elemental selenium and the underlying mechanisms in hydroponic-cultured garlic plant

Abstract

In mining areas, nano-sized elemental selenium (SeNPs), naturally produced through reduction of SeO₃²⁻ by abiotic and biotic processes, usually co-exists with Hg in the environment. Little is known about the fate of SeNPs and how they affect the bioavailability and toxicity of Hg towards plants. In this study, the fate of SeNPs and Hg, and the effect of SeNPs on the mobilization of Hg in a hydroponic-cultured plant were investigated. It was found that SeNPs were less phytotoxic and had stronger capacity for Hg sequestration than SeO₃²⁻and SeO₄²⁻. Synchrotron radiation X-ray fluorescence (SR-XRF) and X-ray absorption near edge structure (XANES) spectroscopy revealed that SeNPs largely captured Hg²⁺via forming HgSe and HgSeNPs to prevent Hg²⁺ from entering the root stele, thus inhibiting translocation and accumulation of Hg in the aerial parts. Apart from immobilizing Hg, SeNPs also promoted the conversion of Hg²⁺ to less toxic RS–Hg–SR and R–Hg–R binding forms in plants. Meanwhile, a portion of SeNPs was transformed into SeMet stored as the nutrient Se source in plant tissues. This study provides insights into the reaction and fate of SeNPs and Hg in water-plant systems, which implies the significance of SeNPs in modulating the fate and toxicity of Hg in mining areas.