Cadmium isotope fractionation during sorption to soil minerals: Lab evidence and field implication.

Stable isotope is a potent geochemical tracer unveiling the dynamic sources of cadmium (Cd) in the environment. However, the sorption process of aqueous Cd onto solid surfaces (e.g., soil) fractionates isotopic signatures, which makes it difficult to interpret its sources and migration processes. Understanding how Cd fractionates during sorption to soil minerals, therefore, provides necessary data to open the isotope fractionation black box of liquid-solid phase partition of Cd. In this study, we explored isotopic fractionation characteristics during Cd sorption to typical soil minerals. Distinct Cd isotope fractionation was observed during sorption, including goethite (∆ 114 / 110 Cd solid − solution = − 0.51 ∼ − 0.47 ‰), montmorillonite (− 0.34 ∼ − 0.32 ‰), quartz (− 0.34 ∼ − 0.30 ‰), gibbsite (− 0.29 ∼ − 0.25 ‰), and kaolinite (− 0.09 ∼ − 0.07 ‰), where lighter isotopes tended to be preferentially sorbed to the solid phase in a reversible manner. We've also conducted a field survey in a historical flooding-affected region to explore Cd isotopic compositions of soil samples adjacent to a polluted creek. Distinct isotopic signatures for surficial soils and deep soils were observed, which was depicted by a binary mixing mode. Leaching of Cd from mine tailings to the creek, as well as its re-adsorption to soil during historical flooding events both led to preferential enrichment of light isotopes in the solid phase, which was consistent with findings from lab sorption experiments. Mineralogical analyses including EPMA, TOF-SIMS, Mössbauer spectra, XRD, and chemical extraction tests, were applied to unveil how Cd was bound to soil minerals at field. Possible linkage between lab and field data were discussed on the basis of these findings. Results from this study are encouraging for future application of Cd isotopes for source tracing. [Display omitted] • How Cd isotopes fractionate during sorption to soil minerals were explored. • Lighter isotopes tend to be preferentially sorbed to the solid phase reversibly. • Field survey was conducted in a flooding-affected area. • Lab fractionation data were used to correct field source apportionment. [ABSTRACT FROM AUTHOR]