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2018 | OriginalPaper | Buchkapitel

Synthesis and Properties Characterization of Crystalline Polyferric Sulfate Adsorbent Used for Treating High As(III)-content Contaminated Water

verfasst von : Pingchao Ke, Zhihong Liu

Erschienen in: Extraction 2018

Verlag: Springer International Publishing

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Abstract

A crystalline polyferric sulfate (PFS) adsorbent was synthesized by oxidizing and precipitating ferrous ions under atmospheric conditions. The morphology, structure, composition and specific surface area (SSA) and adsorptive efficacy to As (III) of the adsorbent were characterized by SEM/EDS and TEM images, XRD patterns, FT-IR spectra, BET SSA analyses and adsorption experiments. The adsorbent presents as morphology of near-spherical aggregate and good crystallinity. A small amount of goethite co-precipitated with PFS in the case of the initial ferrous concentration of 1 mol/L and increased the SSA of the aggregates. The absorbent with co-precipitation of goethite showed good adsorption to As(III) and good filtering performance in the high As(III)-content solution of 10–100 mg/L under acidic, neutral and alkaline conditions (pH 2.09–9.01), and its maximal adsorption capacity and adsorption efficiency were 7911 μg/g and 96% separately. After Adsorption, the stability of the absorbents adsorbing As(III) were evaluated by TCLP tests, and the results indicated that the absorbents adsorbing As(III) were extremely stable, and the concentration of arsenic in all leaching solutions were less than 0.01 mg/L.

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Nazari AM, Radzinski R, Ghahreman A (2017) A review of arsenic metallurgy: treatment of arsenical minerals and the immobilization of arsenic. Hydrometallurgy 147:258–281CrossRef

Hopkin W (1989) The problem of arsenic disposed in non-ferrous metals production. Environ Geochem Health 3–4(11):101–112CrossRef

Pettine M, Campampanella L, Millero FJ (1999) Arsenite oxidation by H₂O₂ in aqueous solutions. Geochimica Cosmochimica Acta 63:2727–2735CrossRef

Ouzounis K, Katsoyiannis I, Zouboulis A, Mitrakas M (2015) Is the coagulation-filtration process with Fe(III) efficient for As(III) removal from groundwaters. Separat Sci Technol 50:1587–1592CrossRef

Mohan D, Pittman JRC (2007) Arsenic removal from water/wastewater using adsorbents—a critical review. J Hazardous Mater 142:1–53CrossRef

Cui J, Che D, Zhang J, Duan S (2015) Groundwater arsenic removal by coagulation using ferric (III) sulfate and polyferric sulfate: a comparative and mechanistic study. J Environ Sci 32:42–53CrossRef

Mertens J, Casentini B, Masion A, Pothig R, Wehrli B, Furrer G (2012) Polyaluminum chloride with high Al₃₀ content as removal agent for arsenic-contaminated well water. Water Res 46:53–62CrossRef

Tresintsi S, Simeonidis K, Vourlias G, Stavropoulos G, Mitrakas M (2012) Kilogram-scale synthesis of iron oxy-hydroxides with improved arsenic removal capacity: study of Fe(II) oxidation precipitation parameters. Water Res 46:5255–5267CrossRef

Zouboulis AI, Moussas PA, Vasiiakou F (2008) Polyferric sulphate: Preparation, characterization and application in coagulation experiments. J Hazardous Mater 155:459–468CrossRef

10.

Zhang X, Wang X, Chen Q, Lv Y, Han X, Wei Y, Xu T (2017) Batch Preparation of high basicity polyferric sulfate by hydroxide substitution from bipolar membrane electrodialysis. ACS Sustain Chem Eng 5:2292–2301CrossRef

11.

Fan M, Asce S, Browm RC, Wheelock TD, Laabs FC (2002) Synthesis, characterization, and coagulation of polymeric ferric sulfate. J Environ Eng 128(6):483–490CrossRef

12.

Harris B (2003) The removal of arsenic from process solutions: theory and industrial practice. In: Young C, Alfantazi A, Anderson C, James A, Dreisinger D, Harris B (eds) Paper presented at the Hydrometallurgy Proceedings 5th international symposium. TMS, Warrendale, pp 1889–1902

13.

Paul MR (2012) Arsenic encapsulation using Portland cement with ferrous sulfate/lime and Terra-band^TM technologies-Microcharacterization and leaching studies. Sci Total Environ 420:300–312CrossRef

14.

De Klerk RJ, Jia Y, Daenzer R, Gomez MA, Demopoulos GP (2012) Continuous circuit coprecipitation of arsenic (V) with ferric iron by lime neutralization: Process parameter effects on arsenic removal and precipitate quality. Hydrometallurgy 111:65–72CrossRef

15.

Streat M, Hellgardt K, Newton N (2008) Hydrous ferric oxide as an adsorbent in water treatment Part 1. Preparation and physical characterization. Process Safety Environ Protect 86:1–9CrossRef

16.

Hlavay J, Polyak K (2005) Determination of surface properties of iron hydroxide-coated alumina adsorbent prepared for removal of arsenic from drinking water. J Colloid Int Sci 284(1):71–77CrossRef

17.

Hodi M, Polyak K, Hlavay J (1995) Removal of poolutants for drinking water by combined ion-exchange and adsorption methods. Environ Int 21:325–331CrossRef

18.

Kurokawa H, Senna M (2006) Bench scale control of the crystallite size and morphology of goethite particles by different ferrous source. Mater Sci Eng, B 135:55–59CrossRef

19.

Liao S, Wang J, Zhu D, Ren L, Zhou W, Ding GJ (2006) Structural characteristics of goethite and its B-loaded oxides. Acta Pedol Sin 43(5):742–748 (In Chinese)

20.

Lakshmipathira P, Narasimhan BRV, Prabhskar S, Raju GB (2006) Adsorption of arsenate on synthetic goethite from aqueous solutions. J Hazard Mater 136(2):281–287CrossRef

Titel: Synthesis and Properties Characterization of Crystalline Polyferric Sulfate Adsorbent Used for Treating High As(III)-content Contaminated Water
verfasst von: Pingchao Ke
Zhihong Liu
Verlag: Springer International Publishing
Buch: Extraction 2018
Print ISBN: 978-3-319-95021-1

Electronic ISBN: 978-3-319-95022-8

Copyright-Jahr: 2018
DOI: https://doi.org/10.1007/978-3-319-95022-8_99

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