Complexation at the edges of hydrotalcite: The cases of arsenate and chromate

Sorption of CrO42- and HAsO42- by hydrotalcite, in its chloride form, was studied as a function of anion concentration. In both cases, the shape of the isotherms is langmuirian. The maximum uptake of CrO42- equals the ion-exchange capacity of the solid, whereas sorption of HAsO42- saturates at a hig...

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Detalles Bibliográficos
Autor principal: Jobbagy, Matias
Publicado: 2013
Materias:
Adsorption
Arsenate
Chromate
Hydrotalcite
Layered double hydroxides
Surface complexation
Anion concentrations
Arsenate uptake
Charge reversal
Chloride concentrations
Chloride ions
Electrophoretic behavior
Equilibrium concentration
Hydrotalcite surfaces
Hydrotalcites
Ion exchange capacity
Particle charge
Surface complex
Chromates
Dyes
Negative ions
Chlorine compounds
arsenic acid
chloride ion
chromic acid
hydrotalcite
article
complex formation
crystal structure
electrophoresis
ion exchange
isotherm
pH
priority journal
Aluminum Hydroxide
Arsenates
Hydrogen-Ion Concentration
Magnesium Hydroxide
Surface Properties
Acceso en línea:https://bibliotecadigital.exactas.uba.ar/collection/paper/document/paper_00219797_v393_n1_p314_Jobbagy
http://hdl.handle.net/20.500.12110/paper_00219797_v393_n1_p314_Jobbagy
Aporte de:
Biblioteca Digital - Facultad de Ciencias Exactas y Naturales (UBA) de Universidad de Buenos Aires
Descripción
Sumario:Sorption of CrO42- and HAsO42- by hydrotalcite, in its chloride form, was studied as a function of anion concentration. In both cases, the shape of the isotherms is langmuirian. The maximum uptake of CrO42- equals the ion-exchange capacity of the solid, whereas sorption of HAsO42- saturates at a higher value. Chloride ions inhibit the uptake of both anions, the amount of sorbed CrO42- declining rapidly to zero. The uptake of HAsO42-, however, attains a constant value at high chloride concentrations. The excess of arsenate uptake follows, at constant pH, a langmuirian dependence with equilibrium concentration and decreases with increasing pH, depicting a marked change in slope at pHpQa3. CrO42- and HAsO42- have notable, albeit different, effects on the electrophoretic behavior of hydrotalcite; the positive particle charge is screened almost completely by CrO42-, whereas sorption of HAsO42- produces charge reversal. These results reflect the formation of inner-sphere arsenate surface complexes at the edges of hydrotalcite particles. The underlying rationale is discussed in terms of the crystal structure of hydrotalcite surfaces. © 2012 Elsevier Inc.

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