Aggregation Behavior of Nitrilotriacetamide (NTAmide) Ligands in Thorium(IV) Extraction from Acidic Medium: Small-Angle Neutron Scattering, Fourier Transform Infrared, and Theoretical Studies.

Two tripodal amides obtained from nitrilotriacetic acid with n -butyl and n -octyl alkyl chains (HBNTA( L I ) and HONTA( L II ), respectively) were studied for the extraction of Th(IV) ions from nitric acid medium. The effect of the diluent medium, i.e., n -dodecane alone and a mixture of n -dodecane and 1-decanol, onto aggregate formation were investigated using small angle neutron scattering (SANS) studies. In addition, the influence of the ligand structure, nitric acid, and Th(IV) loading onto ligand aggregation and third-phase formation tendency was discussed.The L I /L II exist as monomers ( aggregarte radius for L I : 6.0 Å; L II :7.4 Å) in the presence of 1-decanol, whereas L II forms dimers ( aggregarte radius for L II :9.3 Å; L I does not dissolve in n -dodecane) in the absence of 1-decanol. The aggregation number increases for both the ligands after HNO 3 and Th(IV) loading. The maximum organic concentration (0.050 ± 0.004 M) of Th(IV) was reached without third-phase formation for 0.1 M L I /L II dissolved in 20% isodecanol +80% n -dodecane. The interaction of 1-decanol with L II and HNO 3 /Th(IV) with amidic oxygens of L I /L II results in shift of carbonyl stretching frequency, as shown by attenuated total reflectance-Fourier transform infrared (ATR-FTIR) studies. The structural and bonding information of the Th- L I /L II complex were derived from the density functional theoretical (DFT) studies. The molecular dynamics (MD) simulations suggested that the aggregation behavior of the ligand in the present system is governed by the population of hydrogen bonds by phase modifier around the ligand molecules. Although the theoretical studies suggested higher Gibbs free energy of complexation for Th 4+ ions with L I than L II, the extraction was found to be higher with the latter, possibly due to the higher lipophilicity and solubility of the Th- L II aggregate in the nonpolar media.