Key questions for
the study of chemical bonding in actinide compounds
are the degree of covalency that can be realized in the bonds to different
donor atoms and the relative participation of 5f and 6d orbitals.
A manifold of theoretical approaches is available to address these
questions, but hitherto no comprehensive assessments are available.
Here, we present an in-depth analysis of the metal–ligand bond
in a series of actinide metal–organic compounds of the [M(salen)2] type (M = Ce, Th, Pa, U, Np, Pu) with the Schiff base N,N′-bis(salicylidene)ethylenediamine
(salen). All compounds except the Pa complex (only included in the
calculations) have been synthesized and characterized experimentally.
The experimental data are then used as a basis to quantify the covalency
of bonds to both N- and O-donor atoms using simple electron-density
differences and the quantum theory of atoms in molecules (QTAIM) with
interacting quantum atoms. In addition, the orbital origin of any
covalent contributions was studied via natural population analysis
(NPA). The results clearly show that the bond to the hard, charged
O-donor atoms of salen is consistently not only stronger but also
more covalent than bonds to the softer N-donor atoms. On the other
hand, in a comparison of the metals, Th shows the most ionic bond
character even compared to its 4f analogue Ce. A maximum of the covalency
is found for Pa or Np by their absolute and relative covalent bond
energies, respectively. This trend also correlates with a significant
f- and d-orbital occupation for Pa and Np. These results underline
that only a comprehensive computational approach is capable of fully
characterizing the covalency in actinide complexes.
Two series of isostructural tetravalent actinide amidinates [AnX((S)-PEBA) 3 ] (An = Th, U, Np; X = Cl, N 3 ) bearing the chiral (S,S)-N,N′-bis(1-phenylethyl)benzamidinate ((S)-PEBA) ligand have been synthesized and thoroughly characterized in solid and in solution. This study expands the already reported tetravalent neptunium complexes to the lighter actinides thorium and uranium. Furthermore, a rare Ce(IV) amidinate [CeCl((S)-PEBA) 3 ] was synthesized to compare its properties to those of the analogous tetravalent actinide complexes. All compounds were characterized in the solid state using singlecrystal XRD and infrared spectroscopy and in solution using NMR spectroscopy. Quantum chemical bonding analysis including also the isostructural Pa and Pu complexes was used to characterize the covalent contributions to any bond involving the metal cation. Th shows the least covalent character throughout the series, even substantially smaller than for the Ce complex. For U, Np, and Pu, similar covalent bonding contributions are found, but a natural population analysis reveals different origins. The 6d participation is the highest for U and decreases afterward, whereas the 5f participation increases continuously from Pa to Pu.
Tetradentate N2O2-type Schiff base complexes with tetravalent 4f- and 5f-block metals, [M(salpn)2] (H2salpn = N,N′-disalicylidene-1,3-diaminopropane; M = Ce, Th, U, Np, and Pu), were characterised both in the solid state and in solution.
Complexation by small
organic ligands controls the bioavailability
of contaminants and influences their mobility in the geosphere. We
have studied the interactions of Cm3+, as a representative
of the trivalent actinides, and Eu3+, as an inactive homologue,
with glucuronic acid (GlcA) a simple sugar acid. Time-resolved laser-induced
luminescence spectroscopy (TRLFS) shows that complexation at pH 5.0
occurs only at high ligand to metal ratios in the form of 1:1 complexes
with standard formation constants log β0 = 1.84 ± 0.22 for Eu3+ and log β0 = 2.39 ± 0.19
for Cm3+. A combination of
NMR, QMMM, and TRLFS reveals the structure of the complex to be a
half-sandwich structure wherein the ligand binds through its carboxylic
group, the ring oxygen, and a hydroxyl group in addition to five to
six water molecules. Surprisingly, Y3+, which was used
as a diamagnetic reference in NMR, prefers a different coordination
geometry with bonding through at least two hydroxyl groups on the
opposite side of a distorted GlcA molecule. QMMM simulations indicate
that the differences in stability among Cm, Eu, and Y are related
to ring strain induced by smaller cations. At higher pH a stronger
complex was detected, most likely due to deprotonation of a coordinating
OH group.
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