posted on 2023-08-10, 09:43authored byHongqian Yin, Heng Yao, Wei Yuan, Che-Jen Lin, Xuewu Fu, Runsheng Yin, Bo Meng, Jun Luo, Xinbin Feng
Measuring the isotopic composition of Hg in natural waters
is challenging
due to the ultratrace level of aqueous Hg (ng L–1). At least 5 ng of Hg mass is required for Hg isotopic analysis.
Given the low Hg concentration in natural waters, a large volume of
water (>10 L) is typically needed. The conventional grab sampling
method is time-consuming, laborious, and prone to contamination during
transportation and preconcentration steps. In this study, a DGT (diffusive
gradients in thin films) method based on aminopropyl and mercaptopropyl
bi-functionalized SBA-15 nanoparticles was developed and extended
to determine the concentration and isotopic composition of aqueous
Hg for the first time. The results of laboratory analysis showed that
Hg adsorption by DGT induces ∼ −0.2‰ mass-dependent
fractionation (MDF) and little mass-independent fractionation (MIF).
The magnitude of MDF exhibits a dependence on the diffusion-layer
thickness of DGT. Since Hg-MDF can occur in a broad range of environmental
processes, monitoring the δ202Hg of aqueous Hg using
the DGT method should be performed with caution. Field results show
consistent MIF signatures (Δ199Hg) between the DGT
and conventional grab sampling method. The developed DGT method serves
as a passive sampling method that effectively characterizes the MIF
of Hg in waters to understand the biogeochemical cycle of Hg at contaminated
sites.