Evaluation of Immobilized Biomass Beads for Removing Heavy Metals from Wastewaters

Immobilized biomass beads, which consist of dried and ground sphagnum peat moss immobilized in a porous polysulfone matrix, effectively remove heavy metals from wastewaters under appropriate conditions. This paper examines the procedure for forming the beads and their performance in packed columns....

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Veröffentlicht in:	Water environment research 1995-09, Vol.67 (6), p.943-952
Hauptverfasser:	Spinti, Mark, Zhuang, Hanna, Trujillo, Edward M.
Format:	Artikel
Sprache:	eng
Schlagworte:	ACID MINE DRAINAGE Adsorption Aluminum Biomass BIOSORPTION Freshwater HEAVY METALS Inlets ION EXCHANGE Magnesium Metal ions Potassium Q1 Research Papers Resins Sodium Surface areas Wastewater Wastewater treatment
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container_title	Water environment research
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creator	Spinti, Mark Zhuang, Hanna Trujillo, Edward M.
description	Immobilized biomass beads, which consist of dried and ground sphagnum peat moss immobilized in a porous polysulfone matrix, effectively remove heavy metals from wastewaters under appropriate conditions. This paper examines the procedure for forming the beads and their performance in packed columns. The beads are produced by atomizing an organic dispersion into water, creating droplets that become solid through phase inversion. Increasing the relative biomass content gave slightly lower surface areas. Metal ion breakthrough curves were obtained for metal ions from two actual acid mine drainage wastewaters. The selectivity of the beads for various cations was Fe > Al > Pb > Cu > Cd, Zn > Ca > Mn > Mg > Na. Capacity increases with initial pH of the column after regeneration. Bead titration tests indicate that the immobilized biomass beads have heterogeneous ionogenic adsorption sites. Experimental results also indicate that most of the magnesium removed from water by the immobilized biomass beads is adsorbed and exchangeable with potassium. Under the conditions used here, the immobilized biomass beads have a lower capacity than two commercially available ion exchange resins.
doi_str_mv	10.2175/106143095X133176
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This paper examines the procedure for forming the beads and their performance in packed columns. The beads are produced by atomizing an organic dispersion into water, creating droplets that become solid through phase inversion. Increasing the relative biomass content gave slightly lower surface areas. Metal ion breakthrough curves were obtained for metal ions from two actual acid mine drainage wastewaters. The selectivity of the beads for various cations was Fe > Al > Pb > Cu > Cd, Zn > Ca > Mn > Mg > Na. Capacity increases with initial pH of the column after regeneration. Bead titration tests indicate that the immobilized biomass beads have heterogeneous ionogenic adsorption sites. Experimental results also indicate that most of the magnesium removed from water by the immobilized biomass beads is adsorbed and exchangeable with potassium. 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This paper examines the procedure for forming the beads and their performance in packed columns. The beads are produced by atomizing an organic dispersion into water, creating droplets that become solid through phase inversion. Increasing the relative biomass content gave slightly lower surface areas. Metal ion breakthrough curves were obtained for metal ions from two actual acid mine drainage wastewaters. The selectivity of the beads for various cations was Fe > Al > Pb > Cu > Cd, Zn > Ca > Mn > Mg > Na. Capacity increases with initial pH of the column after regeneration. Bead titration tests indicate that the immobilized biomass beads have heterogeneous ionogenic adsorption sites. Experimental results also indicate that most of the magnesium removed from water by the immobilized biomass beads is adsorbed and exchangeable with potassium. Under the conditions used here, the immobilized biomass beads have a lower capacity than two commercially available ion exchange resins.</abstract><pub>Water Environment Federation</pub><doi>10.2175/106143095X133176</doi><tpages>10</tpages></addata></record>
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subjects	ACID MINE DRAINAGE Adsorption Aluminum Biomass BIOSORPTION Freshwater HEAVY METALS Inlets ION EXCHANGE Magnesium Metal ions Potassium Q1 Research Papers Resins Sodium Surface areas Wastewater Wastewater treatment
title	Evaluation of Immobilized Biomass Beads for Removing Heavy Metals from Wastewaters
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