Abstract
Chlorine K-edge X-ray absorption near edge structure (XANES) in actinideIV hexachlorides, [AnCl6]2− (An = Th–Pu), is calculated with relativistic multiconfiguration wavefunction theory (WFT). Of particular focus is a 3-peak feature emerging from U toward Pu, and its assignment in terms of donation bonding to the An 5f vs. 6d shells. With or without spin–orbit coupling, the calculated and previously measured XANES spectra are in excellent agreement with respect to relative peak positions, relative peak intensities, and peak assignments. Metal–ligand bonding analyses from WFT and Kohn–Sham theory (KST) predict comparable An 5f and 6d covalency from U to Np and Pu. Although some frontier molecular orbitals in the KST calculations display increasing An 5f–Cl 3p mixing from Th to Pu, because of energetic stabilization of 5f relative to the Cl 3p combinations of the matching symmetry, increasing hybridization is neither seen in the WFT natural orbitals, nor is it reflected in the calculated bond orders. The appearance of the pre-edge peaks from U to Pu and their relative intensities are rationalized simply by the energetic separation of transitions to 6d t2gversus transitions to weakly-bonded and strongly stabilized a2u, t2u and t1u orbitals with 5f character. The study highlights potential pitfalls when interpreting XANES spectra based on ground state Kohn–Sham molecular orbitals.
Highlights
Elucidation of the chemical bonding in lanthanide (Ln) and actinide (An) systems is presently the goal of many joint experimental and theoretical efforts
These transitions generate the pre-edge features seen in X-ray absorption near edge structure (XANES) spectroscopy, with intensity patterns and energetic band splittings that report the ligand- eld splitting of the metal atomic orbital (AO) and their contributions to the relevant valence molecular orbitals (MOs) that are involved in the transitions.[57,58,59,60,61]
The present study provides means of interpreting the chemistry of actinide 5f and 6d shells in the context of XANES spectroscopy, from the perspective of MO theory concepts that are familiar to chemists
Summary
Elucidation of the chemical bonding in lanthanide (Ln) and actinide (An) systems is presently the goal of many joint experimental and theoretical efforts. A ligand K-edge measurement, for instance, probes bound core-excited states (ESs) arising from the ligand 1s core transition into unoccupied valence molecular orbitals (MOs) with varying degrees of metal atomic orbital (AO) contributions arising from hybridization, i.e., metal–ligand covalent bonding. These transitions generate the pre-edge features seen in XANES spectroscopy, with intensity patterns and energetic band splittings that report the ligand- eld splitting of the metal AOs and their contributions to the relevant valence MOs that are involved in the transitions.[57,58,59,60,61]
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