Abstract
Calcined layered double hydroxides (LDHs) can be used to remove Sb(V), in the Sb(OH)6− form, from aqueous solutions. Sorption batch experiments showed that the mixed MgAlFe oxides, obtained from calcined hydrotalcite-like compound (3HT-cal), removed Sb(OH)6− through the formation of a non-LDH brandholzite-like compound, whereas the mixed ZnAl oxides, resulting from calcined zaccagnaite-like compound (2ZC-cal), trapped Sb(OH)6− in the interlayer during the formation of a Sb(V)-bearing LDH (the zincalstibite-like compound). The competition effect of coexistent anions on Sb(OH)6− removal was HAsO42− >> HCO3− ≥ SO42− for 2ZC-cal and HAsO42− >> HCO3− >> SO42− for 3HT-cal. Considering the importance of assessing the practical use of calcined LDHs, batch experiments were also carried out with a slag drainage affected by serious Sb(V) pollution (Sb = 9900 μg/L) sampled at the abandoned Su Suergiu mine (Sardinia, Italy). Results showed that, due to the complex chemical composition of the slag drainage, dissolved Sb(OH)6− was removed by intercalation in the interlayer of carbonate LDHs rather than through the formation of brandholzite-like or zincalstibite-like compounds. Both 2ZC-cal and 3HT-cal efficiently removed very high percentages (up to 90–99%) of Sb(V) from the Su Suergiu mine drainage, and thus can have a potential application for real polluted waters.
Highlights
Antimony (Sb) is an element widely present in the environment as a result of both natural processes and anthropogenic sources [1]
In our previous work we showed that calcined synthetic layered double hydroxides (LDHs) with composition like hydrotalcite (with formula Mg6 (Al0.5 Fe0.5 )2 (CO3 )(OH)16 ·4H2 O) and zaccagnaite
At the end of the reaction time the solids were recovered through filtration (0.45 μm pore size polycarbonate filters, Whatman Plc, Little Chalfont, Buckinghamshire, UK), washed with distilled water and dried at room temperature for mineralogical characterization
Summary
Antimony (Sb) is an element widely present in the environment as a result of both natural processes and anthropogenic sources [1]. Sb(III) and Sb(V) prevail, respectively, under reducing and oxidizing conditions as antimonous acid H3 SbO3 and antimonic acid. H3 SbO4 and their dissociation products, with the Sb(OH)6 − anion being the most common and stable aqueous species in a wide range of natural pH values [1,9]. Several studies reported that metal hydroxides and oxohydroxides (e.g., MnOOH, Al(OH) , FeOOH) are good Sb removers, they result more efficient for Sb(III) than Sb(V) under slightly acid to acid conditions [15,16,17,18]. Nano-TiO2 electroactive carbon nanotube (CNT) filter and ZrO2 -carbon nanofibers (ZNC) were tested, respectively, for Sb(III) and simultaneous Sb(III) and Sb(V) removal; in particular, it was reported that
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