We establish that routine B3LYP and MP2 methods give qualitatively wrong conformations for flexible organic systems containing pi systems and that recently developed methods can overcome the known inadequacies of these methods. This is illustrated for a molecule (a conformer of the Tyr-Gly dipeptide) for which B3LYP/6-31+G(d) and MP2/6-31+G(d) geometry optimizations yield strikingly different structures [Mol. Phys. 2006, 104, 559-570]: MP2 predicts a folded "closed-book" conformer with the glycine residue located above the tyrosine ring, whereas B3LYP predicts a more open conformation. By employing different levels of theory, including the local electron correlation methods LMP2 (local MP2) and LCCSD(T0) (local coupled cluster with single, double, and noniterative local triple excitations) and large basis sets (aug-cc-pVnZ, n=D, T, Q), it is shown that the folded MP2 minimum is an artifact caused by large intramolecular BSSE (basis set superposition error) effects in the MP2/6-31+G(d) calculations. The B3LYP functional gives the correct minimum, but the potential energy apparently rises too steeply when the glycine and tyrosine residues approach each other, presumably due to missing dispersion effects in the B3LYP calculations. The PWB6K and M05-2X functionals, designed to give good results for weak interactions, remedy this to some extent. The reduced BSSE in the LMP2 calculations leads to faster convergence with increasing basis set quality, and accurate results can be obtained with smaller basis sets as compared to canonical MP2. We propose LMP2 as a suitable method to study interactions with pi-electron clouds.
A thorough understanding of the chemistry of PuO2 is critical to the design of next-generation nuclear fuels and the long-term storage of nuclear materials. Despite over 75 years of study, the ground-state magnetic structure of PuO2 remains a matter of much debate. Experimental studies loosely indicate a diamagnetic (DM) ground-state, whereas theoretical methods have proposed either a collinear ferromagnetic (FM) or anti-ferromagnetic (AFM) ground-state, both of which would be expected to cause a distortion from the reported Fm3[combining macron]m symmetry. In this work, we have used accurate calculations based on the density functional theory (DFT) to systematically investigate the magnetic structure of PuO2 to resolve this controversy. We have explicitly considered electron-correlation, spin-orbit interaction and noncollinear magnetic contributions to identify a hereto unknown longitudinal 3k AFM ground-state that retains Fm3[combining macron]m crystal symmetry. Given the broad interest in plutonium materials and the inherent experimental difficulties of handling this compound, the results presented in this paper have considerable implications for future computational studies relating to PuO2 and related actinide structures. As the crystal structure is coupled by spin-orbit interactions to the magnetic state, it is imperative to consider relativity when creating computational models.
The magnetic structure of the actinide dioxides (AnO2) remains a field of intense research. A noncollinear relativistic computational study of the AnO2 (An = U, Np) magnetic structure has been completed.
We
confirm that synthetic uranyl hydroxide hydrate metaschoepite
[(UO)24O(OH)6]·5H2O is unstable
against dehydration under dry conditions, and we present a structural
and vibrational spectroscopic study of synthetic metaschoepite and
its ambient temperature dehydration product. Complementary structural
(X-ray diffraction and neutron diffraction) and vibrational spectroscopic
techniques (Raman spectroscopy, infrared spectroscopy, and inelastic
neutron scattering) are used to probe different components of these
species. Analysis of the dehydration product suggests that it contains
both pentagonally coordinated and hexagonally coordinated uranyl ions,
necessitating that some uranyl ions undergo a coordination change
during the dehydration of pentagonally coordinated metaschoepite.
Vibrational spectra of metaschoepite and its dehydration product are
interpreted with power spectra generated from ab initio molecular
dynamics trajectories, allowing assignment of all major features.
We identify the uranyl symmetric stretching modes of the four distinct
uranyl ions in synthetic metaschoepite and clarify the assignment
of lower energy Raman modes in both structures. The coanalysis of
experimental and computational data reveals a strong coupling between
the uranyl stretching modes and hydroxide bending modes in the anhydrous
structure, leading to the presence of several high-energy combination
bands in the inelastic neutron scattering data.
Single-phase
β-UO3 is synthesized by flash heating
UO2(NO3)·6H2O in air to 450
°C and annealing for 60 h under the same conditions. For the
first time, we report the Raman spectra of pure β-UO3. To facilitate the assignment of Raman and infrared vibrational
modes, we use density functional theory with density functional perturbation
theory. By employing a novel analysis scheme that includes the mode
frequencies as well as a quantitative analysis of the mode eigenvectors,
we assign the observed spectral features to individual chemical modes.
In particular, the density functional theory optimized structure,
observed Raman spectrum, and eigenvector analysis suggest the presence
of four crystallographically distinct uranyl ions, one more than has
previously been suggested.
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