Enhanced Removal of Fluoride by Polystyrene Anion
Exchanger Supported Hydrous Zirconium Oxide Nanoparticles
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Abstract
Here we fabricated
a novel nanocomposite HZO-201, an encapsulated
nanosized hydrous zirconium oxide (HZO) within a commercial porous
polystyrene anion exchanger D201, for highly efficient defluoridation
of water. HZO-201 exhibited much higher preference than activated
alumina and D201 toward fluoride removal when competing anions (chloride,
sulfate, nitrate, and bicarbonate) coexisted at relatively high levels.
Fixed column adsorption indicated that the effective treatable volume
of water with HZO-201 was about 7–14 times as much as with
D201 irrespective of whether synthetic solution or groundwater was
the feeding solution. In addition, HZO-201 could treat >3000 BV
of
the acidic effluent (around 3.5 mg F<sup>–</sup>/L) per run
at pH 3.5, compared to only ∼4 BV with D201. The exhausted
HZO-201 could be regenerated by NaOH solution for repeated use without
any significant capacity loss. Such attractive performance of HZO-201
resulted from its specific hybrid structure, that is, the host anion
exchanger D201 favors the preconcentration of fluoride ions inside
the polymer based on the Donnan principle, and the encapsulated nanosized
HZO exhibits preferable sequestration of fluoride through specific
interaction, as further demonstrated by XPS spectra. The influence
of solution pH, competitive anions, and contact time was also examined.
The results suggested that HZO-201 has a great potential in efficient
defluoridation of groundwater and acidic mine drainage