Evaluation of covalence in An(III)- and Ln(III)-complexes by NMR Spectroscopy

Partitioning and transmutation (P&T) facilitates a reduction of the long-term radiotoxicity and heat load of spent nuclear fuel by separation of the actinides and subsequent conversion into shorter-lived or stable nuclides. A chemically demanding key step in this process is the separation of the trivalent actinides from fission lanthanides. This can be achieved by liquid-liquid extraction using highly selective extraction agents, such as nPrBTP (1) or C5-BPP (2). These have high separation factors (>100) for trivalent americium over europium. However, the molecular origin of their selectivity is largely unclear.
NMR spectroscopy on paramagnetic samples allows a separation of the observed paramagnetic shift into a part due to transferred electron spin density (Fermi contact shift, FCS) and a part due to dipolar coupling of electron and nuclear spin (Pseudo contact shift, PCS). Evaluation of the FCS thus allows an assessment of the share of covalence in the metal-ligand bond of the N-donor complexes. Several methods that enable the separation of the shift contributions have been proposed in literature. So-called “model free methods” that do not require structural models of the complexes appear most promising.
We will present and compare the results of different temperature-dependent and temperature-independent model-free methods for complexes of both ligands. The merits, but also the limitations of currently available methods will be discussed in detail. Furthermore, we will evaluate the applicability of temperature-dependent methods for shift separation of Am(III) complexes and give a qualitative assessment on covalence in the bonding of these complexes.