Adsorption of cadmium and lead onto oxidized nitrogen-doped multiwall carbon nanotubes in aqueous solution: Equilibrium and kinetics
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Nitrogen-doped multiwall carbon nanotubes (CNx) were chemically oxidized and tested to adsorb cadmium and lead from aqueous solution. Physicochemical characterization of carbon nanotubes included morphological analysis, textural properties, and chemical composition. In addition, the cadmium adsorption capacity of oxidized-CNx was compared with commercially available activated carbon and single wall carbon nanotubes. Carboxylic and nitro groups on the surface of oxidized CNx shifted the point of zero charge from 6.6 to 3.1, enhancing their adsorption capacity for cadmium and lead to 0.083 and 0.139 mmol/g, respectively, at pH 5 and 25 °C. Moreover, oxidized-CNx had higher selectivity for lead when both metal ions were in solution. Kinetic experiments for adsorption of cadmium showed that the equilibrium was reached at about 4 min. Finally, the small size, geometry, and surface chemical composition of oxidized-CNx are the key factors for their higher adsorption capacity than activated carbon. © Springer Science Business Media B.V. 2009.
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Nitrogen-doped multiwall carbon nanotubes (CNx) were chemically oxidized and tested to adsorb cadmium and lead from aqueous solution. Physicochemical characterization of carbon nanotubes included morphological analysis, textural properties, and chemical composition. In addition, the cadmium adsorption capacity of oxidized-CNx was compared with commercially available activated carbon and single wall carbon nanotubes. Carboxylic and nitro groups on the surface of oxidized CNx shifted the point of zero charge from 6.6 to 3.1, enhancing their adsorption capacity for cadmium and lead to 0.083 and 0.139 mmol/g, respectively, at pH 5 and 25 °C. Moreover, oxidized-CNx had higher selectivity for lead when both metal ions were in solution. Kinetic experiments for adsorption of cadmium showed that the equilibrium was reached at about 4 min. Finally, the small size, geometry, and surface chemical composition of oxidized-CNx are the key factors for their higher adsorption capacity than activated carbon. © Springer Science%2bBusiness Media B.V. 2009.
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Adsorption; EHS; Functionalization; Kinetics; Nitrogen-doped carbon nanotubes; Toxic metals; Water pollution Adsorption capacities; Aqueous solutions; Cadmium adsorption; Chemical compositions; EHS; Functionalizations; Key factors; Kinetic experiment; Morphological analysis; Multi-Wall Carbon Nanotubes; Nitro group; Nitrogen-doped; Nitrogen-doped carbon nanotubes; Oxidized nitrogen; Physico-chemical characterization; Point of zero charge; Single wall carbon nanotubes; Small size; Surface chemical composition; Textural properties; Toxic metals; Activated carbon; Adsorption; Cadmium; Carbon nanotubes; Dewatering; Doping (additives); Metal ions; Nitrogen; Oil spills; Single-walled carbon nanotubes (SWCN); Solutions; Toxic materials; Water pollution; Multiwalled carbon nanotubes (MWCN); activated carbon; cadmium; functional group; lead; multi walled nanotube; nitrogen; proton; single walled nanotube; adsorption kinetics; aqueous solution; article; chemical composition; infrared spectroscopy; morphology; oxidation; pH; physical chemistry; priority journal; Raman spectrometry; scanning electron microscopy; surface charge; temperature; X ray diffraction
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