Adsorption of rare earth elements onto Carrizo sand: Experimental investigations and modeling with surface complexation

摘要

Rare earth element (REE) adsorption onto sand from a well characterized aquifer, the Carrizo Sand aquifer of Texas, has been investigated in the laboratory using a batch method. The aim was to improve our understanding of REE adsorption behavior across the REE series and to develop a Surface complexation model for the REEs, which can be applied to real aquifer-groundwater systems. Our batch experiments show that REE adsorption onto Carrizo sand increases with increasing atomic number across the REE series. For each REE, adsorption increases with increasing pH, such that when pH > 6.0, > 98% of each REE is adsorbed onto Carrizo sand for all experimental solutions, including when actual groundwaters from the Carrizo Sand aquifer are used in the experiments. Rare earth element adsorption was not sensitive to ionic strength and total initial REE concentrations in our batch experiments. It is possible that the differences in experimental ionic strength conditions (i.e., 0.002-0.01 M NaCl) chosen were insufficient to affect REE adsorption behavior. However, cation competition (e.g., Ca, Mg, and Zn) did affect REE adsorption onto Carrizo sand, especially for light rare earth elements (LREEs) at low pH. Rare earth element adsorption onto Carrizo sand can be successfully modeled using a generalized two-layer surface complexation model. Our model calculations suggest that REE complexation with strong surface sites of Carrizo sand exceeds the stability of the aqueous complexes LnOH(2+), LnSO(4)(+), and LnCO(3)(+), but not that of Ln(CO3)(2)(-) or LnPO(4)(o) in Carrizo groundwaters. Thus, at low pH (< 7.3), where major inorganic ligands did not effectively compete with surface sites for dissolved REEs, free metal ion (Ln(3+)) adsorption was sufficient to describe REE adsorption behavior. However, at higher pH (> 7.3) where solution complexation of the dissolved REEs was strong, REEs were adsorbed not only as free metal ion (Ln(3+)) but also as aqueous complexes (e.g., as Ln(CO3)(2)(-) in Carrizo groundwaters). Because heavy rare earth elements (HREEs) were preferentially adsorbed onto Carrizo sand compared to LREEs, original HREE-enriched fractionation patterns in Carrizo groundwaters from the recharge area flattened along the groundwater flow path in the Carrizo Sand aquifer due to adsorption of free- and solution-complexed REEs. Copyright (c) 2005 Elsevier Ltd.