Chitosan selectivity for removing cadmium (II), copper (II), and lead (II) from aqueous phase: pH and organic matter effect
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The aim of this study was to investigate the selectivity of chitosan for cadmium, copper and lead in the presence and absence of natural organic matter (NOM) in different pH solutions. Adsorption isotherms of one and three adsorbates at initial concentration of 5-100 mg/L were carried out in batch reactors at pH 4, 5, or 7 and 25 °C in reactive and clarified water. The chitosan employed had a MW of 107.8 × 103 g/mol and degree of acetylation (DA) of 33.7%25. The chitosan adsorption capacity at pH 4 in reactive water was 0.036, 0.016, 0.010 mmol/g for Pb2 , Cd2 , and Cu2 , respectively, and it decreased for Pb2 and Cd2 in clarified water. Conversely, experiments carried out in clarified water showed that the cadmium adsorption capacity of chitosan was enhanced about three times by the presence of NOM at pH 7: an adsorption mechanism was proposed. Furthermore, it was found that the biosorbent selectivity, in both reactive and clarified water at pH 4, was as follows Cu2 > Cd2 > Pb2 . Finally, the preliminary desorption experiments of Cd2 conducted at pH 2 and 3 reported 68 and 44.8%25 of metal desorbed, which indicated that the adsorption mechanism occurred by electrostatic interactions and covalent bonds. © 2008 Elsevier B.V. All rights reserved.
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The aim of this study was to investigate the selectivity of chitosan for cadmium, copper and lead in the presence and absence of natural organic matter (NOM) in different pH solutions. Adsorption isotherms of one and three adsorbates at initial concentration of 5-100 mg/L were carried out in batch reactors at pH 4, 5, or 7 and 25 °C in reactive and clarified water. The chitosan employed had a MW of 107.8 × 103 g/mol and degree of acetylation (DA) of 33.7%25. The chitosan adsorption capacity at pH 4 in reactive water was 0.036, 0.016, 0.010 mmol/g for Pb2%2b, Cd2%2b, and Cu2%2b, respectively, and it decreased for Pb2%2b and Cd2%2b in clarified water. Conversely, experiments carried out in clarified water showed that the cadmium adsorption capacity of chitosan was enhanced about three times by the presence of NOM at pH 7: an adsorption mechanism was proposed. Furthermore, it was found that the biosorbent selectivity, in both reactive and clarified water at pH 4, was as follows Cu2%2b > Cd2%2b > Pb2%2b. Finally, the preliminary desorption experiments of Cd2%2b conducted at pH 2 and 3 reported 68 and 44.8%25 of metal desorbed, which indicated that the adsorption mechanism occurred by electrostatic interactions and covalent bonds. © 2008 Elsevier B.V. All rights reserved.
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Chitosan; Metals; Selectivity; Sorption Adsorption; Adsorption isotherms; Amines; Atmospheric temperature; Batch reactors; Biogeochemistry; Biological materials; Cadmium; Chitin; Chitosan; Clarification; Copper; Desorption; Dewatering; Hydrogels; Lead; Lead alloys; Organic compounds; Sorption; Adsorption capacities; Adsorption mechanisms; Aqueous phase; Biosorbent; Cadmium adsorptions; Degree of acetylations; Electrostatic interactions; Initial concentrations; Natural organic matters; Organic matters; pH solutions; Selectivity; pH effects; activated carbon; cadmium; chitosan; copper; lead; natural organic matter; water; cadmium; copper; lead; organic matter; pH; removal experiment; sorption; acetylation; adsorption; article; chemical structure; desorption; diffusion; functional morphology; heavy metal removal; infrared spectroscopy; pH measurement; solubility; Acetylation; Adsorption; Cadmium; Chitosan; Copper; Hydrogen-Ion Concentration; Ions; Lead; Magnetic Resonance Spectroscopy; Molecular Weight; Solubility; Solutions; Spectrophotometry, Infrared; Temperature; Thermodynamics; Water
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