Removal of phosphate from water by a Fe–Mn binary oxide adsorbent

Zhang, Gaosheng; Liu, Huijuan; Liu, Ruiping; Qu, Jiuhui

doi:10.1016/j.jcis.2009.03.019

Cited by 369 publications

(175 citation statements)

References 37 publications

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“…The elevated f-potential due to Mn 2+ enrichment benefited the adsorption of negatively-charged Sb(OH) 6 À , which was the main Sb(V) species over a wide pH range of 3-9. The positive electrostatic effect of Mn 2+ on the adsorption of arsenic and phosphate has been reported before (Zhang et al, 2007(Zhang et al, , 2009Stumm and Morgan, 1996). Mn 2+ contributed to a more significant f-potential increase for Mn-oxide, and the more remarkable effect on Sb(V) adsorption was observed thereafter.…”

Section: F-potential Variation After Adsorbing Sb(v) and Mn 2+supporting

confidence: 68%

“…By comparison, the adsorption of Sb(V) decreased the pH iep values, which were 3.2 for FMBO and 3.0 for Mn-oxide. The remarkable shift in pH iep indicated the occurrence of specific adsorption and the formation of surface complexes in the adsorption of Mn 2+ and Sb(V) (Zhang et al, 2009;Hsia et al, 1994). The elevated f-potential due to Mn 2+ enrichment benefited the adsorption of negatively-charged Sb(OH) 6 À , which was the main Sb(V) species over a wide pH range of 3-9.…”

Section: F-potential Variation After Adsorbing Sb(v) and Mn 2+mentioning

confidence: 99%

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Adsorption of antimony(V) onto Mn(II)-enriched surfaces of manganese-oxide and Fe Mn binary oxide

Liu

et al. 2015

Chemosphere

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Section: F-potential Variation After Adsorbing Sb(v) and Mn 2+supporting

confidence: 68%

Section: F-potential Variation After Adsorbing Sb(v) and Mn 2+mentioning

confidence: 99%

Adsorption of antimony(V) onto Mn(II)-enriched surfaces of manganese-oxide and Fe Mn binary oxide

Liu

et al. 2015

Chemosphere

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“…Adsorption of strong acid anions by metal oxides and hydroxides typically decreases with increasing pH [31]. Such a pH effect was observed for the sorption of As(V) onto iron oxides or iron-containing oxides [32,33]. H 2 AsO Lower pH is favorable for the protonation of the sorbent surface.…”

Section: Effect Of Ph and Ionic Strengthmentioning

confidence: 99%

Adsorptive removal of arsenic from water by an iron–zirconium binary oxide adsorbent

Ren

Zhang

Chen

2011

Journal of Colloid and Interface Science

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a b s t r a c tArsenate and arsenite may exist simultaneously in groundwater and have led to a greater risk to human health. In this study, an iron-zirconium (Fe-Zr) binary oxide adsorbent for both arsenate and arsenite removal was prepared by a coprecipitation method. The adsorbent was amorphous with a specific surface area of 339 m 2 /g. It was effective for both As(V) and As(III) removal; the maximum adsorption capacities were 46.1 and 120.0 mg/g at pH 7.0, respectively, much higher than for many reported adsorbents. Both As(V) and As(III) adsorption occurred rapidly and achieved equilibrium within 25 h, which were well fitted by the pseudo-second-order equation. Competitive anions hindered the sorption according to the sequence PO 4 . The ionic strength effect experiment, measurement of zeta potential, and FTIR study indicate that As(V) forms inner-sphere surface complexes, while As(III) forms both inner-and outer-sphere surface complexes at the water/Fe-Zr binary oxide interface. The high uptake capability and good stability of the Fe-Zr binary oxide make it a potentially attractive adsorbent for the removal of both As(V) and As(III) from water.

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“…Many of these adsorbents have shown much promise for the removal of phosphate from water. For example, Zhang et al (2009) reported that a Fe-Mn binary oxide had a high P sorption capacity of 36 mg g at pH 5.6. Harver and Rhue (2008) reported that mixed Al-Fe hydr(oxides) were effective for P removal.…”

Section: Introductionmentioning

confidence: 99%

Adsorption of Phosphate from Aqueous Solution Using an Iron–Zirconium Binary Oxide Sorbent

Ren

Shao

Zhang

2012

Water Air Soil Pollut

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108

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In this study, an iron-zirconium binary oxide with a molar ratio of 4:1 was synthesized by a simple coprecipitation process for removal of phosphate from water. The effects of contact time, initial concentration of phosphate solution, temperature, pH of solution, and ionic strength on the efficiency of phosphate removal were investigated. The adsorption data fitted well to the Langmuir model with the maximum P adsorption capacity estimated of 24.9 mg P/g at pH 8.5 and 33.4 mg P/g at pH 5.5. The phosphate adsorption was pH dependent, decreasing with an increase in pH value. The presence of Cl − , SO 4 2− , and CO 3 2− had little adverse effect on phosphate removal. A desorbability of approximately 53 % was observed with 0.5 M NaOH, indicating a relatively strong bonding between the adsorbed PO 4 3− and the sorptive sites on the surface of the adsorbent. The phosphate uptake was mainly achieved through the replacement of surface hydroxyl groups by the phosphate species and formation of innersphere surface complexes at the water/oxide interface. Due to its relatively high adsorption capacity, high selectivity and low cost, this Fe-Zr binary oxide is a very promising candidate for the removal of phosphate ions from wastewater.

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Removal of phosphate from water by a Fe–Mn binary oxide adsorbent

Cited by 369 publications

References 37 publications

Adsorption of antimony(V) onto Mn(II)-enriched surfaces of manganese-oxide and Fe Mn binary oxide

Adsorption of antimony(V) onto Mn(II)-enriched surfaces of manganese-oxide and Fe Mn binary oxide

Adsorptive removal of arsenic from water by an iron–zirconium binary oxide adsorbent

Adsorption of Phosphate from Aqueous Solution Using an Iron–Zirconium Binary Oxide Sorbent

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