Together with the synthesis and experimental characterization of 14 hybrid materials containing [UO2X4]2− (X=Cl− and Br−) and organic cations, we report on novel methods for determining correlation trends in their formation enthalpy (ΔHf) and observed vibrational signatures. ΔHf values were analyzed through isothermal acid calorimetry and a Density Functional Theory+Thermodynamics (DFT+T) approach with results showing good agreement between theory and experiment. Three factors (packing efficiency, cation protonation enthalpy, and hydrogen bonding energy [
]) were assessed as descriptors for trends in ΔHf. Results demonstrated a strong correlation between
and ΔHf, highlighting the importance of hydrogen bonding networks in determining the relative stability of solid‐state hybrid materials. Lastly, we investigate how hydrogen bonding networks affect the vibrational characteristics of uranyl solid‐state materials using experimental Raman and IR spectroscopy and theoretical bond orders and find that hydrogen bonding can red‐shift U≡O stretching modes. Overall, the tightly integrated experimental and theoretical studies presented here bridge the trends in macroscopic thermodynamic energies and spectroscopic features with molecular‐level details of the geometry and electronic structure. This modeling framework forms a basis for exploring 3D hydrogen bonding as a tunable design feature in the pursuit of supramolecular materials by rational design.
Actinyl-Actinyl interactions (AAIs) occur in pentavalent actinide systems, particularly for Np(V), and lead to complex vibrational signals that are challenging to analyze and interpret. Previous studies have focused on...
Solid-state
uranyl hybrid structures are often formed through unique
intermolecular interactions occurring between a molecular uranyl anion
and a charge-balancing cation. In this work, solid-state structures
of the uranyl tetrachloride anion engaged in uranyl–cation
and uranyl–hydrogen interactions were studied using density
functional theory (DFT). As most first-principles methods used for
systems of this type focus primarily on the molecular structure, we
present an extensive benchmarking study to understand the methods
needed to accurately model the geometric properties of these systems.
From there, the electronic and vibrational structures of the compounds
were investigated through projected density of states and phonon analysis
and compared to the experiment. Lastly, we present a DFT + thermodynamics
approach to calculate the formation enthalpies (ΔH
f) of these systems to directly relate to experimental
values. Through this methodology, we were able to accurately capture
trends observed in experimental results and saw good quantitative
agreement in predicted ΔH
f compared
to the value calculated through referencing each structure to its
standard state. Overall, results from this work will be used for future
combined experimental and computational studies on both uranyl and
neptunyl hybrid structures to delineate how varying intermolecular
interaction strengths relates to the overall values of ΔH
f.
The inner-sphere adsorption of AsO 4 3− , PO 4 3− , and SO 4 2− on the hydroxylated α-Al 2 O 3 (001) surface was modeled with the goal of adapting a density functional theory (DFT) and thermodynamics framework for calculating the adsorption energetics. While DFT is a reliable method for predicting various properties of solids, including crystalline materials comprised of hundreds (or even thousands) of atoms, adding aqueous energetics in heterogeneous systems poses steep challenges for modeling. This is in part due to the fact that environmentally relevant variations in the chemical surroundings cannot be captured atomistically without increasing the system size beyond tractable limits. The DFT + thermodynamics approach to this conundrum is to combine the DFT total energies with tabulated solution-phase data and Nernst-based corrective terms to incorporate experimentally tunable parameters such as concentration. Central to this approach is the design of thermodynamic cycles that partition the overall reaction (here, inner-sphere adsorption proceeding via ligand exchange) into elementary steps that can either be fully calculated or for which tabulated data are available. The ultimate goal is to develop a modeling framework that takes into account subtleties of the substrate (such as adsorption-induced surface relaxation) and energies associated with the aqueous environment such that adsorption at mineral−water interfaces can be reliably predicted, allowing for comparisons in the denticity and protonation state of the adsorbing species. Based on the relative amount of experimental information available for AsO 4 3− , PO 4 3− , and SO 4 2− adsorbates and the well-characterized hydroxylated α-Al 2 O 3 (001) surface, these systems are chosen to form a basis for assessing the model predictions. We discuss how the DFT + thermodynamics results are in line with the experimental information about the oxyanion sorption behavior. Additionally, a vibrational analysis was conducted for the charge-neutral oxyanion complexes and is compared to the available experimental findings to discern the inner-sphere adsorption phonon modes. The DFT + thermodynamics framework used here is readily extendable to other chemical processes at solid−liquid interfaces, and we discuss future directions for modeling surface processes at mineral−water and environmental interfaces.
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