Global ETD Search

171	Mecanismo da decomposição e reações com radicais em acetatos / Decomposition mecanism and radical reactions with acetates Noriberto Araujo Pradie 18 May 2011 (has links) Estudos do mecanismo de reações unimoleculares, das moléculas de acetato de metila e etila, induzidas por absorção multifotônica e de reações bimoleculares com os radicais OH e Cl, usando cálculos ab initio e de funcional de densidade foram realizados neste trabalho. A análise dos cálculos das barreiras de energia e das constantes de velocidade microcanônicas das reações unimoleculares com o formalismo da teoria RRKM, permitiu prever algumas reações cujos produtos não foram determinados experimentalmente. Além disso, semelhanças das geometrias e dos valores de energia de algumas estruturas entre diferentes superfícies de energia, analisadas com cálculos de IRC, permitiram a explicação da viabilidade de determinada via de reação em detrimento de outra. Em outro método, relatado por Forst(1), na determinação das constantes de velocidade variacionais, comparadas com a variação da energia de Gibbs, verificou-se constantes de velocidade microcanônicas menores e a localização dos estados de transição em comprimentos de ligação, também, menores. Nas reações com o radical OH e Cl, a via predominante de reação é o ataque aos hidrogênios do grupo ligado diretamente ao oxigênio da molécula, responsável pelo valor da constante final de mais de 93% nas reações com OH e 99% nas reações com Cl, a 298K, em concordância com os resultados experimentais, em detrimento do ataque ao grupo CH3 da porção carboxilato da molécula. Nas reações com OH, os valores de constante de velocidade calculados mais próximos dos valores experimentais foram obtidos a partir dos resultados com os funcionais mPW1B95-41, para o acetato de metila, e mPW1B95-44, para o acetato de etila, enquanto que nas reações com Cl foram obtidos com o os métodos CCSD(T)//B3LYP para o acetato de metila e CCSD(T)//MP2 para o acetato de etila. Os valores de constante de velocidade da reação com cloro são cerca de dez vezes maiores que aquelas para as reações com radicais OH. As reações com OH e Cl ocorrem em uma única etapa, sem estabilização do intermediário e sem efeito de tunelamento significante. Por sua vez, cálculos da constante de velocidade, pelo método da relação estrutura reatividade (SAR), sobreestimam a reatividade dos hidrogênios dos grupos CH3 na porção carboxilato, em ambos os acetatos, e na porção etóxido do acetato de etila. Este método falha ao descrever a participação de cada grupo na reação com Cl, pois prevê que a reação no grupo CH3 da porção alcóxido passa a ser predominante sobre a reação ao grupo CH2 nas reações do acetato de etila, oposto aos nossos cálculos onde a reação com o grupo CH2 é a predominante. Outra falha do método é na previsão de mesma reatividade para ambos os grupos CH3 no acetato de metila, pois por nossos cálculos a reação ocorre predominantemente no grupo CH3 na porção alcóxido da molécula. / Computational studies on methyl and ethyl acetates molecules using ab initio and density functional calculations exploring the unimolecular mechanism, induced by multiphoton absorption, and the bimolecular reactions with OH and Cl radicals, have been performed in this work. Analysis of the calculated energy barriers and rate constants of unimolecular reactions with the RRKM microcanonical theory, predicts the occurrence of some reactions whose products were not determined experimentally. Furthermore, similarities on geometrical and energetic of some structures between different energy surfaces, analyzed with IRC calculations, allowed the explanation of the viability of a particular reaction pathway over another. Forst\'s method, used to determine variational rate constants, when compared with the variation of Gibbs energy, generates microcanonical rate constants with smaller values and location of transition states in smaller bond lengths. With OH and Cl, the predominant reaction route is the attack on the hydrogens of the group bonded directly to oxygen in the molecule, responsible for more than 93% of the final constant value in reactions with OH and 99% in reactions with Cl , at 298 K, in agreement with the experimental results, while the attack to the CH3 group in the carboxylate portion of the molecule is the less likely to occur. In reactions with OH, the values of the rate constant calculated closer to the experimental values were obtained from the results with functional mPW1B95-41, for methyl acetate, and mPW1B95-44 for ethyl acetate, whereas in reactions with Cl, were obtained with the CCSD(T)//B3LYP method for the methyl acetate and the CCSD(T)//MP2 method for ethyl acetate. The rate constant for the reaction with chlorine are about ten times larger than those for reactions with OH radicals. Reactions with OH and Cl occur in a single step, without stabilization of the intermediary and without significant tunneling effect. The rate constant obtained by the structure-reactivity relationship (SAR) overestimates the reactivity of the hydrogens of the CH3 groups at the carboxylate portion, in both acetates, and at the ethoxide portion of ethyl acetate. This method fails to describe the participation of each group in the reaction with Cl, predicting that the reaction on the CH3 portion of the alkoxide becomes predominant over the reaction on the CH2 group of ethyl acetate, relative to our calculations where the reaction with the CH2 group is predominant. Another flaw by providing the same reactivity for both the CH3 in methyl acetate, is in disagreement with our calculations which indicate that the reaction occurs predominantly in the CH3 group at the alkoxide portion of the molecule. ab initio Acetatos Cinética química Constantes de velocidade Química quântica Termoquímica ab initio Acetates Chemical kinetics Quantum chemistry Rate constants Thermochemistry
172	O modelo de percolação em grafos: Um estudo de condições para a transição de fase do parâmetro crítico / Percolation model on graphs: A study of conditions for phase transition Lebensztayn, Élcio 15 January 2002 (has links) Este trabalho visa a estudar o modelo de percolação independente, de Bernoulli, em grafos, tendo como objetivo principal obter condições que garantam a ocorrência de transição de fase. Iniciamos apresentando as definições e algumas técnicas fundamentais para o modelo de percolação (de elos ou de sítios) em um grafo infinito, conectado e localmente finito. Demonstramos então dois resultados essenciais: os fatos do parâmetro crítico não depender da escolha do vértice e da existência de um aglomerado infinito ter probabilidade 0 ou 1. Também obtemos um limitante inferior para o parâmetro crítico quando o grafo é de grau limitado. Para finalizar esta parte introdutória, analisamos a percolação em grafos particulares, a saber, a rede hipercúbica Z^d (para a qual mostramos a existência de transição de fase em dimensão d >= 2 e a unicidade do aglomerado infinito na fase supercrítica) e alguns tipos de árvores (para as quais apresentamos os parâmetros críticos). Na parte mais importante da dissertação, tendo como base os trabalhos de Benjamini e Schramm, de Häggström, Schonmann e Steif e de Lyons e Peres, introduzimos os conceitos de transitividade, amenabilidade e amenabilidade forte para um grafo. Fazemos uma detalhada discussão destas definições: provamos que a constante de Cheeger ancorada não depende do vértice em que é ancorada, estudamos relações entre os conceitos (amenabilidade e amenabilidade forte são noções distintas, bem como condições necessárias e suficientes para ambas) e calculamos a constante de Cheeger e a constante de Cheeger ancorada para alguns grafos. Finalmente, utilizando a técnica de crescimento do aglomerado, apresentamos para a probabilidade crítica um limitante superior que depende da constante ancorada. Isto nos permite concluir que ocorre transição de fase para qualquer grafo infinito, conectado, fracamente não-amenável (de constante de Cheeger ancorada positiva) e de grau limitado. / This work intends to study independent Bernoulli percolation model on graphs; the main purpose is obtaining conditions for phase transition. We begin presenting the definitions and some basic techniques for bond percolation and site percolation models on infinite, connected, locally finite graphs. We prove two essential results: the critical parameter is independent of the choice of the vertex and the probability that there exists an infinite cluster takes the values 0 and 1 only. We also obtain a lower bound for critical parameter when the graph is of bounded degree. To finish this preliminary part, we analyze percolation on particular graphs, namely the d-dimensional cubic lattice Z^d (for which we prove that there exists phase transition in dimension d >= 2 and the uniqueness of the infinite cluster in supercritical phase) and some trees (for which we present the critical parameters). In the most important part of this essay, founded in the works of Benjamini and Schramm, Häggström, Schonmann and Steif and Lyons and Peres, we introduce the concepts of transitivity, amenability and strong amenability. We discuss in detail these definitions: we prove that anchored Cheeger constant does not depend on the choice of the vertex, we study some relations (amenability and strong amenability are distinct notions, and necessary and sufficient conditions for both) and we obtain Cheeger constant and anchored Cheeger constant for some graphs. Finally, using the growing cluster technique, we present for the critical probability an upper bound that depends on the anchored constant. This permits us to conclude that there exists phase transition on infinite, connected, weakly non-amenable graphs of bounded degree. Amenabilidade Forte Cheeger constants Constantes de Cheeger Percolação em grafos Percolation on graphs Phase transition Strong amenability Transição de fase
173	Proton location in acid center dot center dot center dot pyridine hydrogen bonds of multi-component crystals Seaton, Colin C. 17 April 2014 (has links) No / The design of new functional crystalline materials requires an understanding of the factors that control salt and co-crystal formation. These states often only differ in the location of the proton and are influenced by chemical and crystallographic factors. The interaction between a carboxylic acid and a pyridine is a frequently used supramolecular synthon in crystal engineering which can exist as either a co-crystal (CO2H center dot center dot center dot N) or salt (CO2-center dot center dot center dot HN+). The results of a Cambridge Structure Database search indicate that the nature of the functional groups on the pyridine play a stronger role in selection of the phase than those of the acid. However, the nature of the local hydrogen bonding of the interaction also adjusts the potential for proton transfer. This was demonstrated by ab initio modelling of the energy landscape for binary and ternary co-crystals by inclusion of varying components of the local environment.
174	Towards stimuli-responsive functional nanocomposites : smart tunable plasmonic nanostructures Au-VO2 Jean Bosco Kana Kana January 2010 (has links) <p>The fascinating optical properties of metallic nanostructures, dominated by collective oscillations of free electrons known as plasmons, open new opportunities for the development of devices fabrication based on noble metal nanoparticle composite materials. This thesis demonstrates a low-cost and versatile technique to produce stimuli-responsive ultrafast plasmonic nanostructures with reversible tunable optical properties. Albeit challenging, further control using thermal external stimuli to tune the local environment of gold nanoparticles embedded in VO2 host matrix would be ideal for the design of responsive functional nanocomposites. We prepared Au-VO2 nanocomposite thin films by the inverted cylindrical reactive magnetron sputtering (ICMS) known as hollow cathode magnetron sputtering for the first time and report the reversible tuning of surface plasmon resonance of Au nanoparticles by only adjusting the external temperature stimuli. The structural, morphological, interfacial analysis and optical properties of the optimized nanostructures have been studied. ICMS has been attracting much attention for its enclosed geometry and its ability to deposit on large area, uniform coating of smart nanocomposites at high deposition rate. Before achieving the aforementioned goals, a systematic study and optimization process of VO2 host matrix has been done by studying the influence of deposition parameters on the structural, morphological and optical switching properties of VO2 thin films. A reversible thermal tunability of the optical/dielectric constants of VO2 thin films by spectroscopic ellipsometry has been intensively also studied in order to bring more insights about the shift of the plasmon of gold nanoparticles imbedded in VO2 host matrix.</p> Vanadium dioxide Transition temperature Thermochromism Optical constants Gold nanoparticles Nanocomposites Thermal stimuli-responsive Plasmons
175	Structural stability of solids from first principles theory Magyari-Köpe, Blanka January 2002 (has links) No description available. density functional theory electronic structure high pressure perovskite structure phase transition structural stability geophysics binary alloys elastic constants
176	Micromechanics modeling of the multifunctional nature of carbon nanotube-polymer nanocomposites Seidel, Gary Don 02 June 2009 (has links) The present work provides a micromechanics approach based on the generalized self-consistent composite cylinders method as a non-Eshelby approach towards for assessing the impact of carbon nanotubes on the multi-functional nature of nanocom-posites in which they are a constituent. Emphasis is placed on the eﬀective elastic properties as well as electrical and thermal conductivities of nanocomposites con-sisting of randomly oriented single walled carbon nanotubes in epoxy. The eﬀective elastic properties of aligned, as well as clustered and well-dispersed nanotubes in epoxy are discussed in the context of nanotube bundles using both the generalized self-consistent composite cylinders method as well as using computational microme-chanics techniques. In addition, interphase regions are introduced into the composite cylinders assemblages to account for the varying degrees of load transfer between nanotubes and the epoxy as a result of functionalization or lack thereof. Model pre-dictions for randomly oriented nanotubes both with and without interphase regions are compared to measured data from the literature with emphasis placed on assessing the bounds of the eﬀective nanocomposite properties based on the uncertainty in the model input parameters. The generalized self-consistent composite cylinders model is also applied to model the electrical and thermal conductivity of carbon nanotube-epoxy nanocomposites. Recent experimental observations of the electrical conductivity of carbon nanotube polymer composites have identiﬁed extremely low percolation limits as well as a per-ceived double percolation behavior. Explanations for the extremely low percolation limit for the electrical conductivity of these nanocomposites have included both the creation of conductive networks of nanotubes within the matrix and quantum eﬀects such as electron hopping or tunneling. Measurements of the thermal conductivity have also shown a strong dependence on nanoscale eﬀects. However, in contrast, these nanoscale eﬀects strongly limit the ability of the nanotubes to increase the thermal conductivity of the nanocomposite due to the formation of an interfacial thermal resistance layer between the nanotubes and the surrounding polymer. As such, emphasis is placed here on the incorporation of nanoscale eﬀects, such as elec-tron hopping and interfacial thermal resistance, into the generalized self-consistent composite cylinder micromechanics model. micromechanics carbon nanotube nanocomposite polymer effective properties elastic constants electrical conductivity thermal conductivity percolation Kapitza resistance composite cylinders
177	The Effects Of Carbon Content On The Properties Of Plasma Deposited Amorphous Silicon Carbide Thin Films Sel, Kivanc 01 March 2007 (has links) (PDF) The structure and the energy band gap of hydrogenated amorphous silicon carbide are theoretically revised. In the light of defect pool model, density of states distribution is investigated for various regions of mobility gap. The films are deposited by plasma enhanced chemical vapor deposition system with various gas concentrations at two different, lower (30 mW/cm2) and higher (90 mW/cm2), radio frequency power densities. The elemental composition of hydrogenated amorphous silicon carbide films and relative composition of existing bond types are analyzed by x-ray photoelectron spectroscopy measurements. The thicknesses, deposition rates, refractive indices and optical band gaps of the films are determined by ultraviolet visible transmittance measurements. Uniformity of the deposited films is analyzed along the radial direction of the bottom electrode of the plasma enhanced chemical vapor deposition reactor. The molecular vibration characteristics of the films are reviewed and analyzed by Fourier transform infrared spectroscopy measurements. Electrical characteristics of the films are analyzed by dc conductivity measurements. Conduction mechanisms, such as extended state, nearest neighbor and variable range hopping in tail states are revised. The hopping conductivities are analyzed by considering the density of states distribution in various regions of mobility gap. The experimentally measured activation energies for the films of high carbon content are too low to be interpreted as the difference between Fermi level and relevant band edge. This anomaly has been successfully removed by introducing hopping conduction across localized tail states of the relevant band. In other words, the second contribution lowers the mobility edge towards the Fermi level. QC Physics 1-999
178	Thermally Stimulated Current Study Of Traps Distribution In Tlgases Layered Single Crystals Nasser, Hisham 01 July 2010 (has links) (PDF) Trapping centres and their distributions in as-grown TlGaSeS layered single crystals were studied using thermally stimulated current (TSC) measurements. The investigations were performed in the temperature range of 10&ndash / 160 K with various heating rates between 0.6&ndash / 1.2 K/s. Experimental evidence has been found for the presence of three electrons trapping centres with activation energies 12, 20, and 49 meV and one hole trapping centre located at 12 meV. Their capture cross-sections and concentrations were also determined. It is concluded that in these centres retrapping is negligible as confirmed by the good agreement between the experimental results and the theoretical predictions of the model that assumes slow retrapping. The optical properties of TlGaSeS layered single crystals have been investigated by measuring the transmission and the reflection in the wavelength region between 400 and 1100 nm. The optical indirect transitions with a band gap energy of 2.27 eV and direct transitions with a band gap energy of 2.58 eV were found by analyzing the absorption data at room temperature. The rate of change v of the indirect band gap with temperature was determined from the transmission measurements in the temperature range of 10&ndash / 300 K. The oscillator and the dispersion energies, the oscillator strength, and the zero-frequency refractive index were also reported. The parameters of monoclinic unit cell and the chemical composition of TlGaSes crystals were found by X-ray powder diffraction and energy dispersive spectroscopic analysis, respectively. QC Optics, Light 350-467
179	Structural stability of solids from first principles theory Magyari-Köpe, Blanka January 2002 (has links) No description available. density functional theory electronic structure high pressure perovskite structure phase transition structural stability geophysics binary alloys elastic constants
180	FIRST-PRINCIPLES STUDY ON MECHANICAL PROPERTIES OF CH4 HYDRATE Miranda, Caetano R., Matsuoka, Toshifumi 07 1900 (has links) The structural and mechanical properties of s-I methane hydrate have been investigated by first principles calculations. For the first time, the fully elastic constant tensor of s-I methane hydrate is obtained entirely ab-initio. The calculated lattice parameter, bulk modulus, and elastic constants were found to be in good agreement with experimental data at ambient pressure. The Young modulus, Poisson ratio and bulk sound velocities are estimated from the calculated elastic constants and compared with wave speed measurements available. Mechanical properties lattice parameter Bulk modulus Elastic constants Methane hydrate First-principles calculations ICGH International Conference on Gas Hydrates

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