Interplay of Physically Different Properties Leading to Challenges in Separating Lanthanide Cations -- an Ab Initio Molecular Dynamics and Experimental Study

TL;DR

This study combines ab initio molecular dynamics simulations and experimental measurements to understand the challenges in separating lanthanide cations, revealing that similar adsorption free energies result from a delicate balance of hydration and surface binding properties.

Contribution

It provides a detailed mechanistic insight into the factors influencing lanthanide adsorption, highlighting the role of hydration and binding energy cancellation in separation difficulty.

Findings

Lu(III) and Eu(III) have similar adsorption free energies despite different hydration properties.

Hydration free energy differences are canceled out by differences in silica binding energies.

Disrupting this cancellation could improve lanthanide separation techniques.

Abstract

The lanthanide elements have well-documented similarities in their chemical behavior, which makes the valuable trivalent lanthanide cations (Ln(III)) particularly difficult to separate from each other in water. In this work, we apply ab initio molecular dynamics simulations to compare the free energies (Delta G(ads)) associated with the adsorption of lanthanide cations to silica surfaces at a pH condition where SiO- groups are present. The predicted Delta G(ads) for lutetium (Lu(III)) and europium (Eu(III)) are similar within statistical uncertainties; this is in qualitative agreement with our batch adsorption measurements on silica. This finding is remarkable because the two cations exhibit hydration free energies (Delta G(hyd}) that differ by >2 eV, different hydration numbers, and different hydrolysis behavior far from silica surfaces. We observe that the similarity in Lu(III) and Eu(III) Delta G(ads) is the result of a delicate cancellation between the difference in Eu(III) and Lu(III) hydration (Delta G(hyd})), and their difference in binding energies to silica. We propose that disrupting this cancellation at the two end points, either for adsorbed or completely desorbed lanthanides (e.g., via nanoconfinment or mixed solvents), will lead to effective Ln separation.