posted on 2024-08-02, 06:43authored byKurtis Stanistreet-Welsh, Andrew Kerridge
A RASSCF approach
to simulate the O K-edge XANES spectra
of uranyl
is employed, utilizing three models that progressively improve the
representation of the local crystal environment. Simulations successfully
reproduce the observed three-peak profile of the experimental spectrum
and confirm peak assignments made by Denning. The [UO2Cl4]2– model offers the best agreement with
experiment, with peak positions (to within 1 eV) and relative peak
separations accurately reproduced. Establishing a direct link between
a specific electronic transition and peak intensity is complicated,
as a large number of possible transitions can contribute to the overall
peak profile. Furthermore, a relationship between oxygen character
in the antibonding orbital and the strength of the transition breaks
down when using a variety of orbital composition approaches at larger
excitation energy. Covalency analysis of the U–O bond in both
the ground- and excited-state reveals a dependence on the crystal
environment. Orbital composition analysis reveals an underestimation
of the uranium contribution to ground-state bonding orbitals when
probing O K-edge core-excited states, regardless of the uranyl model
employed. However, improving the environmental model provides core-excited
state electronic structures that are better representative of that
of the ground-state, validating their use in the determination of
covalency and bonding.