Molecular hydrogen : a theoretical investigation into the one electron densities of the first three ¹[sigma] [subscript g]⁺ states /

Bates, Jefferson Earl.

January 2008

Thesis (Honors)--College of William and Mary, 2008. / Includes bibliographical references (leaves 22-23). Also available via the World Wide Web.

Electron cyclotron emission measurements of coherent and broadband density fluctuations in the Alcator C-Mod tokamak

Lynn, Alan Gene

28 August 2008

Not available / text

Electron distribution

Radiometers

Cyclotrons

Plasma radiation

Tokamaks

Berry phase modification to electron density of states and its applications

Xiao, Di

28 August 2008

Not available / text

Geometric quantum phases

Electron distribution

Magnetic fields

Berry phase modification to electron density of states and its applications

Xiao, Di, 1979-

22 August 2011

Not available / text

Geometric quantum phases

Electron distribution

Magnetic fields

Many-body effects in ionic systems

Wilson, Mark

January 1994

The electron density of an ion is strongly influenced by its environment in a condensed phase. When the environment changes, for example due to thermal motion, non-trivial changes in the electron density, and hence the interionic interactions occur. These interactions give rise to many-body effects in the potential. In order to represent this phenomenon in molecular dynamics (MD) simulations a method has been developed in which the environmentally-induced changes in the ionic properties are represented by extra dynamical variables. These extra variables are handled in an extended Lagrangian formalism by techniques analogous to those used in Car and Parrinello's ab initio MD method. At its simplest level (the polarizable-ion model or PIM) induced dipoles are represented. With the PIM it has proven possible to quantitatively account for numerous properties of divalent metal halides, which had previously been attributed to unspecific "covalent" effects. In the solid-state the prevalence of layered crystal structures is explained. Analogous non-coulombic features in liquid structures, in particular network formation in "strong" liquids like ZnCl₂ , have been studied as has network disruption by "modifiers" like RbCl. This work leads to an understanding of the relationship between the microscopic structure and anomalous peaks ("prepeaks") seen in diffraction data of such materials. The PIM was extended to include induced quadrupoles and their effect studied in simulations of AgCl. In the solid-state it is found that the both are crucial in improving the phonon dispersion curves with respect to experiment. In the liquidstate polarization effects lower the melting point markedly. For oxides the short-range energy has been further partitioned into overlap and rearrangement energies and electronic structure calculations are used to parameterize a model in which the radius of the anion is included as an additional degree of freedom. The Bl → B2 phase transition is studied in MgO and CaO and the differences between the new model and a rigid-ion model are analysed.

530.41

Electron cyclotron emission measurements of coherent and broadband density fluctuations in the Alcator C-Mod tokamak

Lynn, Alan Gene, Gentle, Kenneth W.,

January 2004

Thesis (Ph. D.)--University of Texas at Austin, 2004. / Supervisor: Kenneth W. Gentle. Vita. Includes bibliographical references.

Berry phase modification to electron density of states and its applications

Xiao, Di,

January 1900

Thesis (Ph. D.)--University of Texas at Austin, 2007. / Vita. Includes bibliographical references.

Some factors affecting the electron distribution in atoms and molecules

Crossley, Richard J. S.

January 1964

No description available.

Characterization of the electronic structure of complexes containing metal-heteroatom multiple bonds.

Hoppe, Martin Louis.

January 1988

The electronic structure of a variety of metal-heteroatom multiply bonded complexes, including some active alkyne metathesis catalysts, have been investigated using He(I) and He(II) ultraviolet photoelectron spectroscopy (UPS), X-ray photoelectron spectroscopy (XPS) and Fenske-Hall molecular orbital calculations. Utilizing this electronic structure information, confirmation of the proposed mechanism for the alkyne metathesis reaction which involves formation of a metallacyclobutdienyl intermediate was ascertained. Also, the important relationships between metallatetrahedral and metallacyclobutadienyl complexes, both of which have been mentioned as possible intermediates in the alkyne metathesis reaction and for which examples have been prepared and isolated, are discussed in significant detail. In the final chapters the electronic structure of some corresponding metal-nitrogen triply bonded complexes are discussed as well as the results probing the charge distribution in metal-heteroatom multiply bonded systems as determined by the XPS experiment.

Organometallic compounds.

Organomolybdenum compounds.

Transition metal nitrides.

Electron distribution.

Plasma diagnostics

January 1966

[by] J. Charles Ingraham and Sanborn C. Brown. / MIT-1842-36. / Bibliography: p.30-32. / Contract no. DA36-039-AMC-03200(E). U.S. AEC Contract AT(30-1)-1842.

TK7855.M41 R43 no.454

Plasma (Ionized gases)

Electron distribution