Abstract Arsenic (As) and antimony (Sb), with analogy structure, belong to VA group in the
periodic table and pose a great public concern due to their potential carcinogenicity. The …

A lack of knowledge about antimony (Sb) isotope fractionation mechanisms in key
geochemical processes has limited its environmental applications as a tracer. Naturally …

Schwertmannite is a poorly-crystalline Fe (III) oxyhydroxysulfate mineral that may control Sb
(V) mobility in acid sulfate environments, including acid mine drainage and acid sulfate soils …

The recruitment of microorganisms by plants can enhance their adaptability to
environmental stressors, but how root-associated niches recruit specific microorganisms for …

Iron (oxyhydr) oxides, especially ferrihydrite (Fh), abundant in the natural environment, are
frequently applied in controlling the migration of heavy metals like antimony (Sb) and …

We investigated the mechanisms that control Sb (V) sorption and coprecipitation with
ferrihydrite across a range of Sb (V) loadings, and examined the associated effects on Sb (V) …

Antimony (Sb) in natural water has long-term effects on both the ecological environment and
human health. Iron mineral phase transformation (IMPT) is a prominent process for removing …

Organic emerging contaminants (OECs) endure in the environment, accumulating in the
organisms along the food chain, with the significant or potential negative impacts on human …

Iron minerals in nature are pivotal hosts for heavy metals, significantly influencing their
geochemical cycling and eventual fate. It is generally accepted that, vivianite, a prevalent …

Fe (II)-induced phase transformations of secondary iron minerals have attracted
considerable attention due to their influence on antimony (Sb) mobility. However, Fe (II) …