RESUMEN
Solvent extraction of Zr(IV) in an undiluted phosphonium based ionic liquid (IL) and its selective separation from Ln(III) and An(III) has been investigated in the present study. Eu(III)/Am(III) were chosen as the representative Ln(III)/An(III). Tri(hexyl)tetradecylphosphonium nitrate ([P66614 ][NO3 ]) was chosen as IL phase and the feed phase was nitric acid containing the target metal ions. The extraction process was accomplished at different experimental parameters such as the concentration of initial nitric acid, initial feed metal concentration and equilibration time to explore the extractability of the proposed IL towards Zr(IV). The efficient extraction of Zr(IV) without any external ligand in IL phase and negligible extraction of Eu(III)/Am(III) were distinctly discerned leading to noteworthy separation factors for Zr(IV). The loading experiment revealed a noticeable growth of equilibrium concentrations of Zr(IV) in IL phase while that of Eu(III) was very less irrespective of the initial feed concentration. The association of two IL moieties in the complex formation process has been inferred. Nitrate ion was found to be superior as IL anion in terms of metal loading in comparison to other anions. Thermodynamics of extraction and the stripping of the loaded Zr(IV) from IL phase using a suitable stripping solution have also been investigated.
RESUMEN
Both tetrel and pnicogen bonds are known to be induced through σ-/π-holes. This work reports computational and experimental evidence of the carbonyl carbon of acetone hosting a tetrel bond by dispersion rather electrostatic forces, for the first time, while phosphorus of POCl3 sustains pnicogen bonding via the σ-hole. Heterodimers of POCl3 with acetone (CH3COCH3) have been isolated within inert gas matrixes of Ar and N2 at 12 K. Characteristic vibrational bands at PâO stretching of POCl3 and CâO stretching of CH3COCH3 have been obtained in support of the computations. The potential energy surface has been traced computationally using ab initio and density functional methods. CH3COCH3 harboring such a tetrel bond, in itself, is quite intriguing. The interplay of these interactions has been comprehended by the quantum theory of atoms in molecules, natural bond orbital, energy decomposition, electrostatic potential mapping, and noncovalent interaction analyses.
RESUMEN
Geometries of nitromethane homodimers have been revisited using ab initio and density functional methodologies, following their formation within cryogenic matrices, confirmed using infrared spectroscopy. In contrast to the claim that the intermolecular interactions are due to dispersion forces or very weak hydrogen bonds, in the present work, concrete evidence for the prevalence of OâN...O pnicogen bonding has been presented. The pnicogen bonds have been found to be primarily responsible for the characteristic geometry of a homodimer. The formation of a nitromethane dimer with pnicogen bonding stabilization is evidenced using matrix isolation infrared spectroscopy with Ne and Ar matrices and computations. The interactions within homodimers have been characterized using quantum theory of atoms in molecules, natural bond orbital, energy decomposition, electrostatic potential mapping, and noncovalent interaction analyses. The larger intermolecular separations in liquid nitromethane indicated by previous molecular dynamics-based studies alongside the supposed invariance of infrared spectra in the gas phase and liquid phase could have led to the assumption of a lack of intermolecular interactions. However, the prevalence of hydrogen and pnicogen bonds across these larger than usual separations is affirmed by the geometries presented here.