Influences of Particles and Aquatic Colloids on the Oxidation of Sb(III) in Natural Water

Abstract: Antimony (Sb) is a hazardous metalloid that is ubiquitous in the environment. Its toxicity and mobility are strongly influenced by the valence state. Particles and aquatic colloids are abundant in natural water; however, there is little understanding of how Sb­(III) is oxidized by these substances. In this study, cross-flow ultrafiltration is used to separate the substances in natural water samples into macroparticles (>1 μm), microparticles (1–0.1 μm), colloids (<0.1 μm, >1 kDa), and dissolved substances (<1 … Show more

“…61 Sb(III) oxidation solely by O 2 is slow, 62 but active substances such as Fe(III)-NOM can accelerate Sb(III) oxidation. 63 In this study, SAWC oxidised Sb(III) to the more mobile Sb(V) in all solutions tested, which explains the generally low removal of Sb(III) (2.3 < log K d < 3.3). The BC related oxidation of Sb is illustrated in Fig.…”

The efficacy of Pb, As(v) and Sb(iii) removal by biochar is determined by solution chemistry

“…61 Sb(III) oxidation solely by O 2 is slow, 62 but active substances such as Fe(III)-NOM can accelerate Sb(III) oxidation. 63 In this study, SAWC oxidised Sb(III) to the more mobile Sb(V) in all solutions tested, which explains the generally low removal of Sb(III) (2.3 < log K d < 3.3). The BC related oxidation of Sb is illustrated in Fig.…”

The efficacy of Pb, As(v) and Sb(iii) removal by biochar is determined by solution chemistry

“…Therefore, it is expected that Fe–OM colloids, which are ubiquitous in subsurface environments, play a crucial component in Sb mobility in natural environments. 25…”

“…24 Sb can usually form associations with low-molecular-weight ligands and interact with Fe-OM colloids in aquatic environments. 1,25 For example, low Fe(II) and high HA concentrations suppressed the formation of thermodynamically more stable goethite and hematite, which benefit the formation of substantial amounts of Fe(III)-OM colloids that affect the mobility and speciation of Sb under OM-rich conditions. 26 This is also evidenced by Hockmann et al, 27 who observed that >15% of Sb(V) occurred in the colloidal phase at a molar Fe/Sb ratio of 400.…”

“…Therefore, it is expected that Fe-OM colloids, which are ubiquitous in subsurface environments, play a crucial component in Sb mobility in natural environments. 25 The co-transport behaviors of colloids and multiple contaminants have been systematically investigated by utilizing packed column experiments. [29][30][31][32][33] Depending on the physical and solution chemistry conditions of the column system, colloids can either benefit from or prohibit the transport of pollutants under different experimental conditions.…”

Co-transport of ferrihydrite–organic matter colloids with Sb(v) in saturated porous media: implications for antimony mobility

The leaching of antimony and arsenic by simulated acid rain in three soil types from the world’s largest antimony mine area