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Synthesis and microstructural characterization of manganese oxide electrodes for application as electrochemical supercapacitorsBabakhani, Banafsheh Unknown Date
No description available.
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PAMBE Growth and Characterization of Superlattice Structures in NitridesYang, Jing January 2013 (has links)
No description available.
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Caracterização de estado sólido e análise computacional de uma nova forma cristalina do fármaco antifilariose dietilcarbamazina: um sal de ácido maleico / Characterization of solid state and computational analysis of a new crystalline form of the antifilarial drug diethylcarbamazine: a maleic acid saltRibeiro, Leandro 12 August 2011 (has links)
A caracterização no estado sólido de insumos farmacêuticos constitui uma parte muito importante no entendimento de suas propriedades físicas, químicas e farmacológicas. A partir da análise estrutural por difração de raios X em monocristal, pode-se identificar a conformação no estado sólido do fármaco, assim como sua densidade eletrônica. Estes estudos podem ser complementados com dados provenientes da Modelagem Molecular, que compreende um número de ferramentas e métodos computacionais e teóricos que têm como objetivos compreender e prever o comportamento de sistemas reais. Nesse contexto, visando compreender melhor as propriedades de estado sólido apresentadas pelo fármaco anti-filariose dietilcarbamazina (DEC), foi obtido um novo sal, o maleato de dietilcarbamazina (DEC maleato), cujas propriedades foram comparadas com as das estruturas já reportadas, DEC citrato e DEC pura. A DEC maleato foi caracterizada por difração de raios X em monocristal, espectroscopias Raman e Infravermelho e análise térmica. A DEC maleato cristaliza no grupo espacial triclínico PI com dois confôrmeros da molécula de DEC na unidade assimétrica, ambos exibindo caudas etílicas na conformação syn em relação ao anel piperazina, diferentemente do que ocorre na DEC citrato e na DEC pura, nas quais esses fragmentos moleculares apresentam uma conformação anti. A principal interação intermolecular entre o fármaco e o ácido maleico é do tipo N-H•••O, que caracteriza a formação do sal e, consequentemente, do par iônico (DEC)+(maleato)-. Além disso, uma rede complexa de interações intermoleculares não-clássicas do tipo C-H•••O estão presentes entre as moléculas de DEC, DEC-maleato e maleato-maleato, levando a um empacotamento cristalino na forma de um sanduíche, onde os confôrmeros da DEC acomodam-se em colunas intercaladas por bicamadas de íons maleato. Não foram observadas transições de fase estruturais em função da temperatura entre 100 K e temperatura ambiente. No entanto, devido à variação conformacional observada entre as moléculas de DEC, cálculos quânticos foram realizados na fase gasosa, otimizando as conformações moleculares tanto da molécula de DEC neutra quanto da carregada a fim de determinar as características de sua estrutura eletrônica utilizando o método da Teoria do Funcional de Densidade, com o funcional híbrido B3LYP e o conjunto de função de base 6-31++G. Através dos cálculos teóricos foram obtidas quatro novas conformações, uma para DEC neutra e três da carregada, para as quais analisou-se as energias de conformação, os espectros vibracionais simulados e por fim os mapas de potencial eletrostático e os orbitais de fronteira. / The solid state characterization of active pharmaceutical ingredients (API) constitutes an important part in understanding their physical, chemical and pharmacological properties. From the structural analysis by single crystal X-ray diffraction, the API conformation in the solid form, as well as its electronic density, can be identified. These studies can be supplemented with data from the Molecular Modeling, which includes a number of theoretical and computational tools used to understand and to predict the behavior in real systems. In this context, aiming to better comprehend the solid state properties exhibited by the anti-filarial drug diethylcarbamazine (DEC), a new salt was obtained, the diethylcarbamazine maleate (DEC maleate), and its properties were compared with the ones of the reported structures, DEC citrate and pure DEC. The DEC maleate was characterized by single crystal X-ray diffraction, infrared and Raman spectroscopy and thermal analysis. DEC maleate was found to crystallize in the triclinic space group PI with two very similar conformers of the DEC molecule in the asymmetric unit, both exhibiting the ethylic chains in conformation syn in relation to the piperazine ring, unlike what happens to DEC citrate and pure DEC, where these chains are anti related. The main intermolecular interaction between the API and the maleic acid is of the type NH•••O, characterizing the salt formation, and thus, the ionic pair (DEC)+(maleate)-. Moreover, a complex network of no-classical intermolecular interactions of the type CH•••O occur between DEC-DEC, DEC-maleate, and maleate-maleate molecules, leading to a sandwich like crystal packing, where DEC conformers are accommodated in columns intercalated by maleates bilayers. No phase transitions were observed for the molecule structure in function of temperature between 100 K and room temperature. However, due conformational variations observed among DEC molecules of the three structures, quantum calculations were performed in the gas phase, optimizing the molecular conformations of both, the neutral and the charged DEC molecules to determine the characteristics of the electronic structure using the method of Density Functional Theory with the B3LYP hybrid functional and basis set 6-31++G. new conformations it were found, for which geometrical characteristics, conformation energies, vibrational spectra simulation and finally the electrostatic potential maps and the frontier orbitals, were analyzed.
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Structural Characterization and Optical Properties of Group IV Semiconductor AlloysJanuary 2014 (has links)
abstract: ABSTRACT This thesis focuses on structural characterizations and optical properties of Si, Ge based semiconductor alloys. Two material systems are characterized: Si-based III-V/IV alloys, which represent a possible pathway to augment the optical performance of elemental silicon as a solar cell absorber layer, and Ge-based Ge1-ySny and Ge1-x-ySixSny systems which are applicable to long wavelength optoelectronics. Electron microscopy is the primary tool used to study structural properties. Electron Energy Loss spectroscopy (EELS), Ellipsometry, Photoluminescence and Raman Spectroscopy are combined to investigate electronic band structures and bonding properties. The experiments are closely coupled with structural and property modeling and theory. A series of III-V-IV alloys have been synthesized by the reaction of M(SiH3)3 (M = P, As) with Al atoms from a Knudsen cell. In the AlPSi3 system, bonding configurations and elemental distributions are characterized by scanning transmission electron microscopy (STEM)/EELS and correlated with bulk optical behavior. The incorporation of N was achieved by addition of N(SiH3)3 into the reaction mixture yielding [Al(As1-xNx)]ySi5-2yalloys. A critical point analysis of spectroscopic ellipsometry data reveals the existence of direct optical transitions at energies as low as 2.5 eV, well below the lowest direct absorption edge of Si at 3.3 eV. The compositional dependence of the lowest direct gap and indirect gap in Ge1-ySny alloys extracted from room temperature photoluminescence indicates a crossover concentration of yc =0.073, much lower than virtual crystal approximation but agrees well with large atomic supercells predictions. A series of Ge-rich Ge1-x-ySixSny samples with a fixed 3-4% Si content and progressively increasing Sn content in the 4-10% range are grown and characterized by electron microscopy and photoluminescence. The ternary represents an attractive alternative to Ge1-ySny for applications in IR optoelectronic technologies. / Dissertation/Thesis / Ph.D. Physics 2014
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Caracterização de estado sólido e análise computacional de uma nova forma cristalina do fármaco antifilariose dietilcarbamazina: um sal de ácido maleico / Characterization of solid state and computational analysis of a new crystalline form of the antifilarial drug diethylcarbamazine: a maleic acid saltLeandro Ribeiro 12 August 2011 (has links)
A caracterização no estado sólido de insumos farmacêuticos constitui uma parte muito importante no entendimento de suas propriedades físicas, químicas e farmacológicas. A partir da análise estrutural por difração de raios X em monocristal, pode-se identificar a conformação no estado sólido do fármaco, assim como sua densidade eletrônica. Estes estudos podem ser complementados com dados provenientes da Modelagem Molecular, que compreende um número de ferramentas e métodos computacionais e teóricos que têm como objetivos compreender e prever o comportamento de sistemas reais. Nesse contexto, visando compreender melhor as propriedades de estado sólido apresentadas pelo fármaco anti-filariose dietilcarbamazina (DEC), foi obtido um novo sal, o maleato de dietilcarbamazina (DEC maleato), cujas propriedades foram comparadas com as das estruturas já reportadas, DEC citrato e DEC pura. A DEC maleato foi caracterizada por difração de raios X em monocristal, espectroscopias Raman e Infravermelho e análise térmica. A DEC maleato cristaliza no grupo espacial triclínico PI com dois confôrmeros da molécula de DEC na unidade assimétrica, ambos exibindo caudas etílicas na conformação syn em relação ao anel piperazina, diferentemente do que ocorre na DEC citrato e na DEC pura, nas quais esses fragmentos moleculares apresentam uma conformação anti. A principal interação intermolecular entre o fármaco e o ácido maleico é do tipo N-H•••O, que caracteriza a formação do sal e, consequentemente, do par iônico (DEC)+(maleato)-. Além disso, uma rede complexa de interações intermoleculares não-clássicas do tipo C-H•••O estão presentes entre as moléculas de DEC, DEC-maleato e maleato-maleato, levando a um empacotamento cristalino na forma de um sanduíche, onde os confôrmeros da DEC acomodam-se em colunas intercaladas por bicamadas de íons maleato. Não foram observadas transições de fase estruturais em função da temperatura entre 100 K e temperatura ambiente. No entanto, devido à variação conformacional observada entre as moléculas de DEC, cálculos quânticos foram realizados na fase gasosa, otimizando as conformações moleculares tanto da molécula de DEC neutra quanto da carregada a fim de determinar as características de sua estrutura eletrônica utilizando o método da Teoria do Funcional de Densidade, com o funcional híbrido B3LYP e o conjunto de função de base 6-31++G. Através dos cálculos teóricos foram obtidas quatro novas conformações, uma para DEC neutra e três da carregada, para as quais analisou-se as energias de conformação, os espectros vibracionais simulados e por fim os mapas de potencial eletrostático e os orbitais de fronteira. / The solid state characterization of active pharmaceutical ingredients (API) constitutes an important part in understanding their physical, chemical and pharmacological properties. From the structural analysis by single crystal X-ray diffraction, the API conformation in the solid form, as well as its electronic density, can be identified. These studies can be supplemented with data from the Molecular Modeling, which includes a number of theoretical and computational tools used to understand and to predict the behavior in real systems. In this context, aiming to better comprehend the solid state properties exhibited by the anti-filarial drug diethylcarbamazine (DEC), a new salt was obtained, the diethylcarbamazine maleate (DEC maleate), and its properties were compared with the ones of the reported structures, DEC citrate and pure DEC. The DEC maleate was characterized by single crystal X-ray diffraction, infrared and Raman spectroscopy and thermal analysis. DEC maleate was found to crystallize in the triclinic space group PI with two very similar conformers of the DEC molecule in the asymmetric unit, both exhibiting the ethylic chains in conformation syn in relation to the piperazine ring, unlike what happens to DEC citrate and pure DEC, where these chains are anti related. The main intermolecular interaction between the API and the maleic acid is of the type NH•••O, characterizing the salt formation, and thus, the ionic pair (DEC)+(maleate)-. Moreover, a complex network of no-classical intermolecular interactions of the type CH•••O occur between DEC-DEC, DEC-maleate, and maleate-maleate molecules, leading to a sandwich like crystal packing, where DEC conformers are accommodated in columns intercalated by maleates bilayers. No phase transitions were observed for the molecule structure in function of temperature between 100 K and room temperature. However, due conformational variations observed among DEC molecules of the three structures, quantum calculations were performed in the gas phase, optimizing the molecular conformations of both, the neutral and the charged DEC molecules to determine the characteristics of the electronic structure using the method of Density Functional Theory with the B3LYP hybrid functional and basis set 6-31++G. new conformations it were found, for which geometrical characteristics, conformation energies, vibrational spectra simulation and finally the electrostatic potential maps and the frontier orbitals, were analyzed.
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Geochemical, Petrologic, and Structural Characterization at Multiple Scales of Deformation Associated with the Punchbowl Fault, Southern CaliforniaSchulz, Steven E. 01 May 1997 (has links)
Three traverses across the exhumed trace of the Punchbowl fault zone in the 11 Pelona Schist, southern California, were examined at the millimeter to kilometer scales to determine the morphology, deformation mechanisms, and geochemistry of the fault zone in schistose rocks. The Pelona Schist is predominantly a quartz-albite-muscovite-actinolite schist with associated minor metabasalts. The Punchbowl fault zone, which is exhumed 2-4 km, has 44 km of right lateral slip, and is composed of a fault core enveloped by a damaged zone.
The fault core is a region of extreme slip localization that records most fault displacement. Deformation in the fault core is dominated by grain-size reduction accompanied by fluid-dominated alteration, in contrast to the damage zone, where deformation is dominated by brittle and semi-brittle fracturing, cataclasis, and slip. Portions of the Punchbowl fault have multiple fault cores, with each fault core less than 10 cm thick. The thickness of a fault depends upon the type of deformation measured and the scale of observation. Mesoscopic fractures begin 50 m from the fault core, whereas the onset of fault-related microfractures occurs at approximately 40 m from the fault core . A geochemical signature based on whole-rock geochemistry suggests a fault thickness of less than 10 m. Grain-size reduction occurs over a 10 m thick region and mineralogic changes occur over a region 20-30 m thick. Reorientation of preexisting foliation occurs over a zone 30 m thick.
Fault-core morphology and textures are similar to those in the Punchbowl fault to the northwest, where it displaces sedimentary rocks, and the San Gabriel fault, which formed in crystalline rocks. This suggests that the processes that form foliated, finegrained, cataclasite-dominated fault cores of large displacement faults are similar for diverse lithologies. The composition of the fault core is variable along strike, with little geochemical or mineralogical homogenization. Whereas processes that form fault cores are similar, localized interaction of fluids caused compositional variability within the core. Changes in fault composition and fluid-rock interactions may result in different fault properties and behaviors.
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Structural Characterization of Three Southeast Segments of the Clark Fault, Salton Trough CaliforniaBelgarde, Benjamin E. 01 May 2007 (has links)
We examine the structural complexities of a 28-km long part of the Clark fault of the San Jacinto fault zone in southern California in order to better document its lateral extent and the style of deformation of its southeast end. Changes in structural style are observed as the Clark fault’s damage zone widens from ~ 1-2 km in crystalline rocks of the Peninsular Ranges southeastward to ~ 18 km in the sedimentary rocks of the San Felipe-Borrego subbasin of the Salton Trough. The Clark fault extends into the San Felipe-Borrego subbasin as the Arroyo Salada segment for ~ 11-12 km to a newly defined northeast-trending structural boundary. This structural boundary, referred to herein as the Pumpkin Crossing block, is a ~ 3-km wide and ~ 8-km long fault zone dominated by northeast-striking sinistral-normal strike-slip faults. Southeast of the Pumpkin Crossing block the newly defined San Felipe Hills segment extends the Clark fault another ~12-13 km southeast to its intersection with the Extra fault zone. The Clark fault may have nearly 14.5-18 km of right separation represented in the surface deformation of the Arroyo Salada and San Felipe Hills segments, but the total amount of strain is masked by the wide diffuse fault zone with its complex deformation patterns and geometries. The lateral change observed in microseismicity patterns across the Arroyo Salada and San Felipe Hills segment boundary supports our structural interpretations about the existence, location, and structure of this boundary. Vertical patterns in the microseismicity suggest that the Clark fault zone narrows at depth, dips steeply northeast in the subsurface, and must interact with at least one weak decollement layer(s) beneath and/or with the sedimentary basin.
Structural deformation within the late Miocene to Holocene silty- and clay-rich sedimentary basin of the Salton Trough includes features characteristic of strike-slip faults, such as stepovers, conjugate faults, folds, flower structures, and fault bends, as well as many unique structures that include pooch structures, ramp-flat geometries of strike-slip faults, complex en echelon fault zones with localized shear distributed across a high frequency network of faults, and heterogeneous kinematic indicators within individual fault zones.
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Application of MS/MS and Ion Mobility to the Characterization of Secondary and Tertiary Protein StructureMorrison, Lindsay J. 03 November 2014 (has links)
No description available.
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Synthesis, Kinetic Studies, and Structural Investigations of Osmium and Ruthenium ClustersNesterov, Volodymyr 07 1900 (has links)
Addition reactions of ten neutral nucleophiles and seven anionic nucleophiles with the pentaosmium pentadecacarbonyl carbido cluster Os5C(CO)15 have been kinetically studied and several important reactivity trends have been established. The calculated activation parameters support an associative mechanism involving the attack of nucleophiles on the parent cluster in the rate-limiting step. Decarbonylation reactions of neutral arachno clusters Os5C(CO)15L have also been kinetically studied and different reactivity trends have been observed. Reactions of Os5C(CO)15 with both neutral and anionic nucleophiles produce corresponding arachno clusters in good yield. Neutral arachno clusters decarbonylate when heated to yield corresponding nido clusters. All studied anionic arachno clusters are resistant to decarbonylation, but most of them readily react with organic acids to form corresponding hydrido clusters. Reactions of anionic arachno clusters with methyl triflate yielded several new clusters. Exploration of metal-ligand bond lengths in the respective pairs of arachno and nido clusters yielded a valuable conclusion with regard to steric effects prevalent in these molecules. The mechanisms for polyhedral structural rearrangements between arachno and nido derivatives of the pentaosmium carbido cluster have been proposed. Thermolysis of cluster Ru3[Ph2PCH(Me)PPh2](CO)10 in the presence of diphenylacetylene yields alkyne-substituted clusters Ru3(PhCCPh)[Ph2PCH(Me)PPh2](CO)8 and Ru3(PhCCPh)[Ph2PCH(Me)PPh2](CO)7 as the major products. The backbone-modified diphosphine in both clusters has facilitated the growth of single crystals suitable for X-ray crystallography. The kinetics for the conversion between two clusters have been investigated and the calculated activation parameters were found to be inconsistent with a rate-limiting step involving a dissociative loss of CO.
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Physicochemical and Structural Analysis of Polymers as Putative DrugsThompson, Meghan L 01 January 2015 (has links)
Sulfated low molecular weight lignins (LMWLs) have shown good activity as anticoagulants by allosterically inhibiting thrombin, as well as promising agents for treating emphysema through inhibition of elastolysis, oxidation, and inflammation. Sulfated LMWLs are chemo-enzymatically synthesized from starting monomers caffeic, ferulic, and sinapic acid into sulfated dehydropolymers known as CDS, FDS, and SDS. To further the LMWLs’ development as drugs, their structural composition and physicochemical characteristics were defined in this work. The molecular weight distribution profile of the sulfated LMWLs from size exclusion chromatography performed on a high pressure liquid chromatography system (SEC-HPLC) changed from bimodal when no surfactant is used in the mobile phase of the HPLC to unimodal when surfactant is used in the mobile phase. This indicates that some large molecular weight species, likely an aggregate of smaller molecular weight chains, are disrupted when surfactant is present. The resulting estimates of molecular weight calculated when surfactant is used in the mobile phase resulted in peak average molecular weights of 5700 Da for CDS, 7400 Da for FDS, and 4300 Da for SDS. These molecular weights are 17-45% higher and can be considered more accurate than the previously reported molecular weights (CDS: 3320 Da, FDS: 4120 Da, SDS: 3550 Da) because they were measured directly whereas previous estimates were calculated from GPC-HPLC data of the unsulfated LMWL precursors. Elemental analysis and distribution coefficient measurements were also performed on the LMWL library, revealing information about the level of sulfation and hydrophobic character of the sulfated LMWLs.
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