Authors: Wen Po Cheng, Chia Yun Chung, Ruey Fang Yu, Chao Feng Chen

Abstract:

The main objective of this research was to study the differences of aluminum hydrolytic products between two PACl preparation methods. These two methods were the acidification process of freshly formed amorphous Al(OH)₃ and the conventional alkalization process of aluminum chloride solution. According to Ferron test and ²⁷Al NMR analysis of those two PACl preparation procedures, the reaction rate constant (k) values and Al₁₃ percentage of acid addition process at high basicity value were both lower than those values of the alkaline addition process. The results showed that the molecular structure and size distribution of the aluminum species in both preparing methods were suspected to be significantly different at high basicity value.

Keywords: Polyaluminum chloride, Al13, amorphous aluminum hydroxide, Ferron test.

Digital Object Identifier (DOI): doi.org/10.5281/zenodo.1131173

Procedia APA BibTeX Chicago EndNote Harvard JSON MLA RIS XML ISO 690 PDF Downloads 1460

References:

[1] Yan MY, Wang DS, Ni JR, Qu JH, Chow CWK, Liu HL (2008) Mechanism of natural organic matter removal by polyaluminum chloride: effect of coagulant particle size and hydrolysis kinetics. Water Res 42:3361-3370.
[2] Gao BY, Yue QY, Wang BJ (2004) Coagulation efficiency and residual aluminum content of polyaluminum silicate chloride in water treatment. Acta Hydroch Hydrob 32:125-130.
[3] Sinha S, Yoon Y, Amy G, Yoon J (2004) Determining the effectiveness of conventional and alternative coagulants through effective characterization schemes. Chemosphere 57:1115-1122.
[4] Cheng WP, Li CC, Yu RF (2007) Study of the coagulation property of polyaluminum silicate chloride coagulants prepared whit ultrasonic-assisted NaOH dosing. Separation science and technology. Separation science and technology 42:3217-3228.
[5] Zouboulis AI, Tzoupanos N (2010) Alternative cost-effective preparation method of polyaluminium chloride (PAC) coagulant agent: Characterization and comparative application for water/wastewater treatment. Desalination 250: 339-344.
[6] Bi Z, Feng CH, Wang DS, Ge XP, Tang HX (2013) Transformation of planar Mogel Al13 coagulant during the dilution and aging process. Colloids and Surfaces A: Physicochemical and Engineering Aspects 416:73-79.
[7] Lindahl G (1985) Stable solutions of basic aluminium sulphate containing polynucleate aluminium hydroxide sulphate complexes. United States Patent 4536384.
[8] Kudermann G, Blaufuss KH (1993) Method for increasing the molar ratio of aluminum to chlorine in polyaluminum chloride solutions. United States Patent 5254224.
[9] Kerven GL, Larsen PL, Blamey FPC (1995) Detrimental effects of sulfate on the formation of the Al13 tridecameric polycation in synthetic soil solutions. Soil Science Society of America 59: 765-771.
[10] Dufour, P., Process for the preparation of basic polyaluminum chlorosulphates and applications thereof, 1999, United States Patent 5879651.
[11] Haake G, Geiler G, Haupt F (2001) Process for preparing sulfate-containing basic solutions of polyaluminumchloride. United States Patent 6241958.
[12] Liu HJ, Qu JH, Hu CZ, Zhang SJ (2003) Characteristics of nanosized polyaluminum chloride coagulant prepared by electrolysis process. Colloids and Surfaces A: Physicochem. Eng. Aspects 216:139-147.
[13] Hu CZ, Liu HJ. Qua JH (2005) Preparation and characterization of polyaluminum chloride containing high content of Al13 and active chlorine. Colloids and surfaces. A, Physicochemical and engineering aspects 260: 109-117.
[14] Janaína AMP, Marcio S, Enrico D, José CP, José LF (2009) Cristiane A. HenriquesThe kinetics of gibbsite dissolution in NaOH. Hydrometallurgy 96:6-13.
[15] Zhou W, Gao B, Liu L, Wang Y (2006) Al-ferron kinetics and quantitative calculation of Al(Ⅲ) species in polyaluminum coagulants. Colloids and surfaces A 278:235-240.
[16] Cheng WP, Li CC, Yu RF (2008) Preparing polyaluminum chloride coagulants using ultrasonic-assisted NaOH dosing. Environ. Eng. Sci. 25:451-459.
[17] Feng CH, Tang HX, Wang DS (2007) Differentiation of hydroxyl-aluminum species at lower OH/Al ratios by combination of 27Al NMR and Ferron assay improved with kinetic resolution. Colloids and Surfaces A: Physicochemical and Engineering Aspects 305:76-82.
[18] Cheng WP, Li CC, Yu RF (2007) A study on the removal of oranic substances from low turbidity and low-alkalinity water with metal-polysilicate coagulants. Colloids and surfaces A 312:238-244.
[19] Bertsch PM, Parker DR (1996) In: Sposito G (ed) The environmental chemistry of aluminum, 2nd edition. CRC Press, Boca Raton, Florida.
[20] Stol RJ, Van Helden AK, De Bruyn PL (1976) Hydrolysis-precipitation studies of aluminum (III) solutions. 2. A kinetic study and model. J. of Colloid and Interface Sci 57:115-131.
[21] Ye CQ, Wang DS, Shi BY, Ge XP, Qu JH (2007) Formation and transformation of Al13 from freshly formed precipitate in partially neutralized Al(III) solution. Journal of Sol-Gel Science and Technology 41:257-265.
[22] Shen YH, Brian A (1998) Dempsey, Synthesis and speciation of polyaluminum chloride for water treatment. Environment International 24:899-910.
[23] Lydersen E, Salbu B, Poleo A B S, Muniz I P (1991) Formation and dissolution kinetics of Al(OH)3(s) in synthetic freshwater solutions. Water Resources Research 27:351-357.
[24] Wang D S, Tang H X, Gregory J. (2002) Relative importance of charge neutralization and precipitation on coagulation of Kaolin with PACl: Effect of sulfate ion. Environmental Science and Technology 36:1815- 1820.
[25] Lin JL, Huang CP, Chin CJ, Pan JR (2009) The origin of Al(OH)3-rich and Al13-aggregate flocs composition in PACl coagulation. Water Research 43:4285-4295.
[26] Bertsch PM, Thomas GW, Bamhisel RI (1986) Characterization of hydroxy-aluminum solutions by aluminum-27 nuclear magnetic resonance spectroscopy. Soil Science Society of America Journal 50:825-830.
[27] Bi S, Wang C, Cao Q, Zhang C (2004) Studies on the mechanism of hydrolysis and polymerization of aluminum salts in aqueous solution: correlations between the “Core-links” model and “Cage-like” Keggin-Al13 model. Coordination Chemistry Reviews 248:441-455.
[28] Huang L, Tang HX, Wang DS, Wang SF, Deng ZJ (2006) Al(Ⅲ) speciation distribution and transformation in high concentration PACl solutions. 18:872-879.
[29] Wu X, Wang D, Ge X, Tang H (2008) Coagulants of silica microspheres with hydrolyzed Al(Ⅲ)-significance of Al13 and Al13 aggregates. Colloids and surfaces A 330:72-79.
[30] Kloprogge JT, Don S, Geus JW, Jansen JBH (1993) The effects of concentration and hydrolysis on the oligomerization and polymerization of Al(III)as evident from the Al NMR chemical shifts and line widths. Journal of Non-Crystalline Solids l60:144-151.
[31] Hsu PH, Bates TF (1964) Formation of X-ray amorphous and crystalline aluminum hydroxide. Miner. Mag. 33:749-768.