Your search keyword '"Cooper, Valentino R."' showing total 3 results

1. van der Waals density functionals built upon the electron-gas tradition: Facing the challenge of competing interactions.

Author

Berland, Kristian, Arter, Calvin A., Cooper, Valentino R., Kyuho Lee, Lundqvist, Bengt I., Schröder, Elsebeth, Thonhauser, T., and Hyldgaard, Per

Subjects

VAN der Waals forces, DENSITY functional theory, ELECTRON gas, METAL-organic frameworks, GROUND state (Quantum mechanics)

Abstract

The theoretical description of sparse matter attracts much interest, in particular for those ground-state properties that can be described by density functional theory. One proposed approach, the van der Waals density functional (vdW-DF) method, rests on strong physical foundations and offers simple yet accurate and robust functionals. A very recent functional within this method called vdW-DF-cx [K. Berland and P. Hyldgaard, Phys. Rev. B 89, 035412 (2014)] stands out in its attempt to use an exchange energy derived from the same plasmon-based theory from which the nonlocal correlation energy was derived. Encouraged by its good performance for solids, layered materials, and aromatic molecules, we apply it to several systems that are characterized by competing interactions. These include the ferroelectric response in PbTiO3, the adsorption of small molecules within metal-organic frameworks, the graphite/diamond phase transition, and the adsorption of an aromatic-molecule on the Ag(111) surface. Our results indicate that vdW-DF-cx is overall well suited to tackle these challenging systems. In addition to being a competitive density functional for sparse matter, the vdWDF- cx construction presents a more robust general-purpose functional that could be applied to a range of materials problems with a variety of competing interactions. [ABSTRACT FROM AUTHOR]

Published

2014

2. An application of the van der Waals density functional: Hydrogen bonding and stacking interactions between nucleobases.

Author

Cooper, Valentino R., Thonhauser, T., and Langreth, David C.

Subjects

*VAN der Waals forces, *HYDROGEN bonding, *QUANTUM chemistry, *MATHEMATICAL transformations, *MECHANICAL buckling, *PHYSICAL sciences

Abstract

We apply the van der Waals density functional (vdW-DF) to study hydrogen bonding and stacking interactions between nucleobases. The excellent agreement of our results with high level quantum chemical calculations highlights the value of the vdW-DF for first-principles investigations of biologically important molecules. Our results suggest that, in the case of hydrogen-bonded nucleobase pairs, dispersion interactions reduce the cost of propeller twists while having a negligible effect on buckling. Furthermore, the efficient scaling of DFT methods allowed for the easy optimization of separation distance between nucleobase stacks, indicating enhancements in the interaction energy of up to 3 kcal/mol over previous fixed distance calculations. We anticipate that these results are significant for extending the vdW-DF method to model larger vdW complexes and biological molecules. [ABSTRACT FROM AUTHOR]

Published

2008

3. The effect of octahedral tilting on proton binding sites and transition states in pseudo-cubic perovskite oxides.

Author

Gomez, Maria A., Griffin, Mary A., Jindal, Saryu, Rule, Kristin D., and Cooper, Valentino R.

Subjects

BIOCHEMISTRY, OXIDE minerals, PEROVSKITE, ELECTROCHEMISTRY, CONSTRUCTION materials, FUEL cells

Abstract

Proton conducting oxide ceramics have shown potential for use in fuel cell technologies. Understanding the energy pathways for proton conduction could help us design more efficient fuel cell materials. This paper describes how octahedral tilting affects the relative energies of proton binding sites, transition states, and conduction pathways in cubic and pseudo-cubic perovskites. First, the structure for cubic and pseudo-cubic forms of BaTiO3, BaZrO3, CaTiO3, and CaZrO3, is found. Even when cubic symmetry is enforced, CaTiO3, and CaZrO3 exhibit octahedral tilting distortions characteristic of orthorhombic phases while BaTiO3 and BaZrO3 remain undistorted. Octahedral tilting gives rise to proton binding sites facilitating inter- and intra-octahedral proton transfer while the proton binding sites of undistorted perovskites facilitate only intra-octahedral proton transfer. The nudged elastic band method is used to find minimum energy paths between the proton binding sites. As distortions increase, inter-octahedral proton transfer barriers decrease while intra-octahedral proton transfer barriers increase. Concurrently, rotational barriers from oxygens facilitating inter-octahedral proton transfer increase while rotational barriers from oxygens facilitating intra-octahedral proton transfer decrease. Intra-octahedral transfer is the rate-limiting step to the lowest energy extended proton conduction pathway in all the perovskites considered. [ABSTRACT FROM AUTHOR]

Published

2005