Hans V. Volden

Bio: Hans V. Volden is an academic researcher from University of Oslo. The author has contributed to research in topics: Gas electron diffraction & Bond length. The author has an hindex of 25, co-authored 159 publications receiving 2256 citations.

Molecular conformation of 2,2′-bithiophene determined by gas phase electron diffraction and ab initio calculations

Abstract: Gas phase electron diffraction was performed at 97–98°C on 2,2′-bithiophene and the experimental data show the existence of two conformations, anti -like and syn -like, with torsional angles of 148(3) and 36(5)° and conformational weights 56(4) and 44(4)%, respectively, which are in agreement with ab initio calculations using standard 3-21G ∗ and 6-31G ∗ basis sets.

Molecular single-bond covalent radii for elements 1-118.

Abstract: A self-consistent system of additive covalent radii, R(AB)=r(A) + r(B), is set up for the entire periodic table, Groups 1-18, Z=1-118. The primary bond lengths, R, are taken from experimental or theoretical data corresponding to chosen group valencies. All r(E) values are obtained from the same fit. Both E-E, E-H, and E-CH 3 data are incorporated for most elements, E. Many E-E' data inside the same group are included. For the late main groups, the system is close to that of Pauling. For other elements it is close to the methyl-based one of Suresh and Koga [J. Phys. Chem. A 2001, 105, 5940] and its predecessors. For the diatomic alkalis MM' and halides XX', separate fits give a very high accuracy. These primary data are then absorbed with the rest. The most notable exclusion are the transition-metal halides and chalcogenides which are regarded as partial multiple bonds. Other anomalies include H 2 and F 2 . The standard deviation for the 410 included data points is 2.8 pm.

Thermal decomposition of the non-interstitial hydrides for the storage and production of hydrogen.

Abstract: This review focuses on key aspects of the thermal decomposition of multinary or mixed hydride materials, with a particular emphasis on the rational control and chemical tuning of the strategically important thermal decomposition temperature of such hydrides, Tdec. An attempt is also made to predict the thermal stability of as-yet unknown, elusive or even unknown hydrides. The future of a particularly promising class of materials for hydrogen storage, namely the catalytically enhanced complex metal hydrides, is discussed. The predictions are supported by thermodynamics considerations, calculations derived from molecular orbital (MO) theory and backed up by simple chemical insights and intuition.

Chemical thermodynamics of uranium

Abstract: I. Introduction. Background. Focus of the review. Review procedure and results. The NEA-TDB data base system. Presentation of the selected data. II. Standards and Conventions. Symbols, terminology and nomenclature. Units and conversion factors. Standard and reference conditions. Fundamental physical constants. III. Selected Uranium Data. IV. Selected Auxiliary Data. V. Discussion of Data Selection. Elemental uranium. Aqua ions. Oxide, hydride and hydroxide species. VI. Discussion of Auxiliary Data Selection. Reference list. Authors list. Formula list. Discussion of selected references. Ionic strength corrections. Assigned uncertainties. The estimation of entropies.