Vapor-liquid equilibria of natural gas-crude oil systems,

Standing, Marshall Burton, Katz, Donald La Verne,

January 1900

Abstract of Thesis (PH. D.)--University of Michigan, 1941. / An article, by M.B. Standing and D.L. Katz, reprinted from Petroleum technology, November 1943.

The prediction of two-phase flows

Papadopoulos, Christos

January 1990

No description available.

532

Gas phase; Particulate phase; Equations

A Study of the Flow Patterns in the Gas Phase of a Bubbling Column

Hill, Peter

12 1900

The gas phase flow patterns in a bubbling column were investigated, using tracer methods to establish the residence time dis­tributive An analogue computer obtained the moments if this distribution directly. The air flow rate and column height were varied. The results showed that as the air flow rate in­creased, although the voidage increased, the mean residence tine decreased. Thus an increasing proportion if the gas phase behaved as a stagnant volume. The results are correlated in terms of a mixed region model. Other work showed that an increase of liquid viscosity, or the inhibition of coalescence, affected only the stagnant volume. The rate of coalescence was investigated and an estimate of its magnitude was obtained. / Thesis / Master of Engineering (ME)

flow pattern

gas phase

bubbling column

Photodissociation of gas phase organic cations

Huang, Fu-shiuan

January 1991

No description available.

Chemistry, Physical

Spectroscopy and photodynamics of gas phase ions

Faulk, James Donald

January 1991

No description available.

Chemistry, Physical

The Examination of the Stability and Reactivity of Select Transition Metal β-Diketonate Complexes during Gas-Phase Ligand Exchange Reactions

Hunter, Gerald, Jr.

January 2009

No description available.

Chemistry

mass spectrometry

gas-phase

ligand reactions

Applications of silver ionic liquids

Wang, Yu

January 2015

No description available.

660

Electronic Structure, Intermolecular Interactions and Electron Emission Dynamics via Anion Photoelectron Imaging

Grumbling, Emily Rose

January 2010

This dissertation explores the use of anion photoelectron imaging to interrogate electronic dynamics in small chemical systems with an emphasis on photoelectron angular distributions. Experimental ion generation, mass selection, laser photodetachment and photoelectron imaging were performed in a negative-ion photoelectron imaging spectrometer described in detail. Results for photodetachment from the simplest anion, H⁻, are used to illustrate fundamental principles of quantum mechanics and provide basic insight into the physics behind photoelectron imaging from a pedagogical perspective. This perspective is expanded by introducing imaging results for additional, representative atomic and small molecular anions (O⁻, NH₂⁻ and N₃⁻) obtained at multiple photon energies to address the energy-dependence of photoelectron angular distributions both conceptually and semi-quantitatively in terms of interfering partial photoelectron waves. The effect of solvation on several of these species (H⁻, O⁻, and NH₂⁻) is addressed in photoelectron imaging of several series of cluster anions. The 532 and 355 nm energy spectra for H⁻(NH₃)n and NH₂⁻(NH₃)n (n = 0-5) reveal that these species are accurately described as the core anion solute stabilized electrostatically by n loosely coordinated NH3 molecules. The photoelectron angular distributions for solvated H⁻ deviate strongly from those predicted for unsolvated H⁻ as the electron kinetic energy approaches zero, indicating a shift in the partial-wave balance consistent with both solvation-induced perturbation (and symmetry-breaking) of the H⁻ parent orbital and photoelectron-solvent scattering. The photoelectron energy spectra obtained for the cluster series [O(N₂O)n]⁻ and [NO(N₂O)n]⁻ indicate the presence of multiple structural isomers of the anion cores, the former displaying sharp core-switching at n = 4, the latter isomer coexistence over the entire range studied. The photoelectron angular distributions for detachment from the O⁻(N₂O)n and NO⁻(N₂O)n isomers deviate strongly from those expected for bare O⁻ and NO⁻, respectively, in the region of an anionic shape resonance of N₂O, suggesting resonant photoelectron-solvent scattering. Partial-wave models for two-centered photoelectron interference in photodetachment from dissociating I₂⁻ is presented and discussed in the context of previous results. New time-resolved photoelectron imaging results for I₂⁻, for both parallel and perpendicular pump and probe beam polarizations, are presented and briefly discussed. Finally, new ideas and directions are proposed.

anions

clusters

gas-phase

laser spectroscopy

photodetachment dynamics

photoelectron imaging

Gas Phase Studies of Organic Reaction Mechanisms

Conner, Keyanna M

01 January 2015

The competition between substitution (SN2) and elimination (E2) in nucleophilic reactions of alkyl halides has had a profound influence on the development of physical organic chemistry and remains an important testing ground for identifying reactivity patterns in gas-phase organic chemistry. Here, the competition between substitution and elimination, as well as the regioselectivity of E2 reactions have been examined in the gas phase. By doing so, the intrinsic reactivity patterns can be probed in the absence of solvation effects. The SN2 and E2 reactions of a large set of alkyl bromides with varying substitution patterns at the α- and β-carbons were studied in the gas phase using naphthoate and phenoxide-based dianion nucleophiles. The experiments were performed in a quadrupole ion trap mass spectrometer equipped with electrospray ionization. The experimental work was supported by calculations at the MP2/6-31+G(d,p)//MP2/6-31+G(d) level. The naphthoate is a weaker base and leads to more products from the SN2 pathway. In accord with generalizations from condensed-phase results, primary bromides generally prefer substitution pathways and secondary bromides prefer eliminations. In the gas phase, polarizability is more important, and the highest SN2 reactivity is observed when the β-carbon is 2° - steric crowding from β-substituents is not as significant for un-solvated nucleophiles. In addition, the data confirms that alkyl substituents at the β-carbon have a greater accelerating effect on E2 reactions than those at the α-carbon. Finally, computed data based on lowest enthalpy pathways provide poor descriptions of the reactions of the larger alkyl bromides and are skewed toward crowded systems that offer stabilizing, nonbonded interactions at the expense of conformational freedom. An investigation of regiochemical preferences of E2 reactions was also explored by synthesizing and analyzing the product distributions of a set of deuterium-labeled compounds capable of Saytzeff and Hofmann elimination. Gas-phase reactions of these substrates with dianion nucleophiles indicate that as expected, there is a preference for the Saytzeff product, which is also preferred in solution. This is the first study of E2 regioselectivity in the gas phase for a simple alkyl system.

Gas Phase Studies

Organic Reaction Mechanisms

Organic Chemistry

Effects of metal complexation on heparin-like disaccharides : a combined experimental and theoretical approach / Effets de la complexation de métaux avec des disaccharides d'héparine : une approche combinant expérience et théorie

Ortiz Trujillo, Daniel

29 November 2012

L'héparine (Hp) est un polysaccharide sulfaté appartenant à la famille des glycosaminoglycanes (GAGs), et est constitué d'unités de répétition disaccharidiques composées d’un acide hexauronique lié par une liaison α1→4 à un résidu hexosamine. La sulfatation de ce polysaccharide peut avoir lieu sur les positions 6-O ou N du glucosamine, mais également sur la position 2-O de l'acide hexauronique. En général, les GAGs sont O-liés aux chaînes latérales des protéoglycanes, et sont associés à un nombre important d'activités physiologiques, généralement reliées à leur interaction avec diverses protéines. Dans certains cas, cette interaction peut-être influencée par la liaison à ces complexes Hp/protéine d'ions métalliques naturels. Ceux-ci influencent l'affinité, la spécificité et la stabilité de ces complexes. En dépit de sa pertinence, le mécanisme par lequel un cation métallique module l'activité de l'héparine au sein des complexes Hp-protéine, reste largement méconnu.Un éventail de stratégies et d'outils ont été développés afin de faciliter la détermination des structures primaires des biomolécules par spectrométrie de masse en tandem (MS/MS). En effet, la caractérisation structurale de l'héparine sulfatée et de ses complexes métalliques a été soutenue par le développement de techniques de spectrométrie de masse. Dans certains cas, il a été observé que lors de l'activation par dissociation induite par collision (CID), certains de ces isomères d'héparine partageaient à peu près les mêmes schémas de fragmentation, compliquant de ce fait le processus d'identification de ces composés. Néanmoins, des études réalisées au LAMBE ont montré que la réactivité en phase gazeuse des ions métalliques pouvait aider à la différenciation d'isomères saccharidiques. Ces études peuvent être utiles non seulement du point de vue purement analytique, mais également parce que le comportement différent des isomères envers un métal donnée conduit à informations sur le processus d'interaction Hp/Métal mis en jeu. Cela peut s’avérer important pour interpréter les mécanismes biologiques mentionnées auparavant.Dugourd et al ont récemment rapporté les spectres optiques et les motifs de photodissociation de différents oligosaccharides sous irradiation UV. En terme de chemins de fragmentation, il a été observé que les spectres de photodissociation Ultraviolet (UVPD) apparaissaient être plus informatifs que la CID en raison de clivages à travers les cycles supplémentaires, qui fournissent une information sur la position du groupe sulfate. Le spectre optique des disaccharides sulfatés est caractérisé par une bande large et intense centrée vers 240 nm. Suite à ces résultats, nous nous sommes intéressés au couplage de la spectroscopie optique et des calculs théoriques pour les disaccharides d'héparine, et avons employé la spectroscopie UVPD afin d’obtenir des informations complémentaires sur les interactions de ces sucres avec les métaux.Comme décrit auparavant, les processus CID représentent un outil très précieux pour la caractérisation structurale des biomolécules. Motivés par des travaux antérieurs publiés par W. Hase et K. Song, nous avons collaboré avec les groupe de R. Spezia et T. Riera afin de parvenir à une meilleure compréhension du processus MS/MS des sucres et des peptides protonés. Les mécanismes CID de modèles simples, N-Formylalanylamide (HCO-Ala-NH2) et Galactose-6-Sulfate, ont été étudiés par des simulations de dynamique moléculaire QM+MM et des expériences MS/MS. Les objectifs de cette thèse étaient les suivants: i) explorer la possibilité d'utiliser le calcium métallique à des fins analytiques ii) fournir de nouvelles données sur la nature de l’interaction Hp/Ca2+ en utilisant une stratégie multi-approches combinant plusieurs techniques expérimentales et de calculs quantiques iii) étudier le processus CID de différents systèmes par des simulations de dynamique moléculaire. / Heparin (Hp) is a sulfated polysaccharide composed of repeating dissacharide units of hexauronic acid linked (α1→4) to an hexosamine residue that belongs to the family of glycosaminoglycans (GAGs). Sulfation can occur at the 6-O and/or N-positions of the gluscosamine, as well as the 2-O position of the hexauronic acid. GAGs usually exist as the O-linked side-chains of proteoglycans, associated with numerous important physiological activities, generally related to their interaction with diverse proteins. In some cases, this interaction can be influenced by the binding of natural metal ions to these Hp/protein complexes. Their role is usually pertained to the affinity, specificity and stability of these complexes. Despite its relevance, the mechanism by which the cation modulates heparin activity in Hp-protein complexes is largely unknown. A range of strategies and tools has been developed to facilitate the determination of primary structures of analyte molecules of interest via tandem mass spectrometry (MS/MS). In fact, structural characterization of heparin sulfated and its metal complexes has been sustained by the development of mass spectrometry techniques. In some cases, it was observed that upon collision-induced dissociation (CID) activation, some of these heparin-like isomers share nearly the same fragmentation patterns, turning the identification process into a complicated step. Nevertheless, a few years ago, our group showed that the gas-phase reactivity of metal ions can shed light into differentiating isomeric saccharides. These studies can be useful for two reasons: just for purely analytical purposes and also because the different behavior of the isomers towards the metal gives information about the Hp/Metal interaction. This might be important to explain the biological considerations mentioned before. Moreover, Dugourd et al recently reported the optical spectra and photodissociation patterns of different Hp oligosaccharides under UV irradiation. In terms of fragmentation pathways, it was observed that Ultraviolet photodissociation (UVPD) spectra appear to be more informative than CID due to additional cross-ring cleavages that provide information about the sulfate group location. Remarkably, the optical spectrum is characterized by an intense broad band centered at 240 nm for sulfated disaccharides. Following these findings, we became interested in coupling optical spectroscopy and theoretical calculations in heparin disaccharides and developing an alternative strategy to characterize these metal interactions. As described before, CID processes are commonly used in several fields and represent a very valuable tool in protein or carbohydrate characterization. Motivated by previous work published by W. Hase and K. Song, we collaborated with R.Spezia and T. Riera’s group in order to achieve a better understanding of the MS/MS process of protonated peptides and sugars. CID mechanisms of simple models, N-Formylalanylamide (HCO-Ala-NH2) and Galactose-6-Sulfate, were studied by QM+MM chemical dynamics simulations and MS/MS experiments.

Chimie en phase gazeuse

Gas-phase chemistry

Molecular dynamics

Electrospray ionization