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  • About
  • The Global ETD Search service is a free service for researchers to find electronic theses and dissertations. This service is provided by the Networked Digital Library of Theses and Dissertations.
    Our metadata is collected from universities around the world. If you manage a university/consortium/country archive and want to be added, details can be found on the NDLTD website.
1

Studium acidobazických vlastností derivátů bilirubinu metodou kapilární zónové elektroforesy / Study of acid-base properties of bilirubin derivatives using capillary zone electrophoresis

Kupcová, Kristýna January 2012 (has links)
in English The concise summary of literary information about bilirubin and its structure derivative ranarubin is the topic of this thesis. The experimental part is dedicated to investigation of some properties of this substances and their comparison. The rate of degradation and acid- base behaviour was monitored under the laboratory conditions using capillary zone electrophoresis. The results point to differences in their behaviour.
2

Modélisation des relations structure / propriétés de transport de charge dans les matériaux pour l'électronique organique / Structure/charge transport relationships in molecular and polymeric materials for organic electronics through atomistic modeling

Gali, Sai Manoj 10 October 2017 (has links)
Les avancées technologiques et l'intégration massive de dispositifs électroniques nanométriques dans les objets de notre vie quotidienne ont généré une explosion des coûts de R&D, de conception et de production, ainsi que des inquiétudes sociétales quant à l'impact environnemental des déchets électroniques. En raison de procédés de production moins coûteux et à faible impact environnemental, de leur souplesse d’utilisation et de la possibilité de moduler leurs propriétés à l’infini, les molécules et polymères organiques constituent une classe de matériaux prometteuse pour la mise au point de nouveaux dispositifs électroniques. L’électronique organique couvre ainsi un vaste domaine d’applications, parmi lesquelles se trouvent les diodes électroluminescentes, les transistors à effet de champ ou les cellules photovoltaïques. Bien que la plupart de ces dispositifs soient déjà commercialisés, les processus gouvernant leur efficacité à l’échelle atomique sont loin d’être entièrement compris et maîtrisés. C’est en particulier le cas des processus de transport de charge, qui interviennent dans tous ces dispositifs.L'objectif de cette thèse est d’apporter une compréhension fondamentale des processus de transport de charge dans les semiconducteurs organiques, à partir d'approches théoriques combinant dynamique moléculaire, calculs quantiques et simulations Monte Carlo. Ce travail est développé suivant trois axes principaux:(I) Etude des relations liant l'organisation structurale et les propriétés de transport de cristaux moléculaires, et du rôle des fluctuations énergétiques dans des matériaux polymères amorphes. Des simulations Monte Carlo Cinétique (KMC) couplés au formalisme de Marcus-Levich-Jortner pour le calcul des taux de transfert ont été effectués afin de déterminer les mobilités des électrons et des trous au sein de dix structures cristallines de dérivés phtalocyanines. Dans une deuxième étude, une approche similaire a été employée afin de décrire les propriétés de transport de charge au sein d'un copolymère amorphe de fluorène-triphénylamine, ainsi que l'impact des fluctuations énergétiques sur ces dernières. La méthodologie développée permet d'obtenir, pour un faible coût calculatoire, une estimation semi-quantitative des mobilités des porteurs de charge dans ce type de système.(II) Etude de l'impact de contraintes mécaniques sur les propriétés de transport de matériaux organiques cristallins. La réponse électronique et les propriétés de transport de matériaux organiques soumis à une contrainte mécanique ont été étudiés à l'aide de simulations de dynamique moléculaire et de calculs DFT. Le rubrène cristallin et ses polymorphes, ainsi que les dérivés du BTBT, ont été considérés pour cette étude, qui révèle un couplage électromécanique inhabituel entre les différents axes cristallographiques. Les résultats démontrent en particulier que l'anisotropie structurale des monocristaux organiques conduit à une anisotropie du couplage électromécanique.(III) Etude du rôle du polyélectrolyte dans la conductivité des complexes conducteurs. Le polystyrène substitué par du bis(sulfonyl)imide est utilisé comme un contre-ion et un dopant dans les complexes conducteurs PEDOT-polyélectrolytes. En complément des analyses expérimentales, des simulations de dynamique moléculaire couplées à des calculs DFT ont été effectuées dans ces systèmes afin d'analyser l'impact de la conformation et de l'état de protonation du polyélectrolyte sur la conductivité du complexe formé avec le PEDOT.Les études décrites ci-dessus, réalisées sur différents types de matériaux en couplant différents types d'approches théoriques, ont permis d'apporter une compréhension fondamentale des propriétés de transport dans les semiconducteurs organiques. Elles mettent en particulier en évidence l'impact de l'organisation structurale, des interactions intermoléculaires et de l'application de contraintes mécaniques sur la mobilité des porteurs de charges dans ces matériaux. / With the advancement of technology, miniaturized electronic devices are progressively integrated into our everyday lives, generating concerns about cost, efficiency and environmental impact of electronic waste. Organic electronics offers a tangible solution paving the way for low-cost, flexible, transparent and environment friendly devices. However, improving the functionalities of organic (opto) electronic devices such as light emitting diodes and photovoltaics still poses technological challenges due to factors like low efficiencies, performance stability, flexibility etc. Although more and more organic materials are being developed to meet these challenges, one of the fundamental concerns still arises from the lack of established protocols that correlate the inherent properties of organic materials like the chemical structure, molecular conformation, supra-molecular arrangement to their resulting charge-transport characteristics.In this context, this thesis addresses the prediction of charge transport properties of organic semiconductors through theoretical and computational studies at the atomistic scale, developed along three main axes :(I) Structure-charge transport relationships of crystalline organic materials and the role of energetic fluctuations in amorphous polymeric organic semiconductors. Kinetic Monte-Carlo (KMC) studies employing the Marcus-Levich-Jortner rate formalism are performed on ten crystalline Group IV phthalocyanine derivatives and trends linking the crystalline arrangement to the anisotropic mobility of electrons and holes are obtained. Subsequently, KMC simulations based on the simpler Marcus formalism are performed on an amorphous semiconducting fluorene-triphenylamine (TFB) copolymer, to highlight the impact of energetic fluctuations on charge transport characteristics. A methodology is proposed to include these fluctuations towards providing a semi-quantitative estimate of charge-carrier mobilities at reduced computational cost.(II) Impact of a mechanical strain on the electronic and charge transport properties of crystalline organic materials. Crystalline rubrene and its polymorphs, as well as BTBT derivatives (well studied high mobility organic materials) are subjected to mechanical strain and their electronic response is analyzed. Employing tools like Molecular Dynamic (MD) simulations and plane wave DFT (PW-DFT) calculations, unusual electro-mechanical coupling between different crystallographic axes is demonstrated, highlighting the role of inherent anisotropy that is present in the organic single crystals which translates in an anisotropy of their electro-mechanical coupling.(III) Protonation-dependent conformation of polyelectrolyte and its role in governing the conductivity of polymeric conducting complexes. Polymeric bis(sulfonyl)imide substituted polystyrenes are currently employed as counter-ions and dopants for conducting poly(3,4-ethylenedioxythiophene) (PEDOT), resulting in PEDOT-polyelectrolyte conducting complexes. Employing MD simulations and DFT calculations, inherent characteristics of the polyelectrolyte like its acid-base behavior, protonation state and conformation, are analyzed in conjunction with available experimental data and the role of these characteristics in modulating the conductivity of resulting PEDOT-polyelectrolyte conducting complexes is highlighted.The above studies, performed on different organic electronic systems, emphasize the importance of inherent characteristics of organic materials in governing the charge transport behavior in these materials. By considering the inherent characteristics of organic electronic materials and systematically incorporating them into simulation models, accuracy of simulation predictions can be greatly improved, thereby serving not only as a tool to design new, stable and high performance organic materials but also for optimizing device performances.
3

Estudos teórico e experimental de propriedades estruturais e eletrônicas da molécula emodina em solvente e em bicamadas lipídicas / Theoretical and Experimental Studies of Structural and Electronic Properties of Emodin Molecule in Solvent and Lipid Bilayers

Cunha, Antonio Rodrigues da 08 August 2014 (has links)
A Emodina (EMH) é uma das antraquinonas mais abundantes na natureza. Essa molécula vem sendo largamente usada como material de estudo científico por apresentar diversas atividades farmacológicas, tais como antiviral, antitumoral, antifungal, digestiva e outras. É conhecido que a Emodina em solução aquosa alcalina pode sofrer mais de um processo de desprotonação, apresentando-se na forma desprotonada, EM-, após a primeira desprotonação. Nesta tese de doutorado estudamos as propriedades estruturais e eletrônicas da molécula Emodina em meio solvente e em bicamadas lipídicas a fim de caracterizar as propriedades relacionadas à espectroscopia UV-Vis, à reatividade e à termodinâmica dessa molécula nesses ambientes. Realizamos cálculos quânticos com a Emodina em vácuo e em meio solvente, onde consideramos todos os possíveis sítios de desprotonação. Como resultados desses cálculos, identificamos os sítios da primeira, segunda e terceira desprotonação. Calculamos o pKa1 da Emodina em água e o pK*a1 em metanol através de simulações computacionais com o método Monte Carlo e cálculos quânticos, com o solvente descrito com o modelo contínuo polarizável. Nossos melhores valores para o pKa1 da Emodina determinados nesses solventes foram 8.4±0.5 e 10.3±1.5, que estão em boa concordância com os valores experimentais, (pKa1=8.0±0.2 e pK*a1=11.1±0.1) obtidos nesta tese para Emodina em água e metanol, respectivamente. Adicionalmente realizamos simulações com Dinâmica Molecular com as espécies EMH e EM- em bicamada lipídica de DMPC, para investigar a nível atômico as interações dessas espécies com a bicamada e determinar as posições preferenciais dessas espécies nesse ambiente anfifílico. Os resultados dessas simulações mostraram que as espécies EMH e EM- ficam inseridas na bicamada, na região polar dos lipídios, próximos aos gliceróis. Esses resultados corroboram as nossas medidas do espectro de absorção dessas espécies em bicamada lipídica, onde mostramos de forma qualitativa, que ambas as espécies ficam inseridas na bicamada, na região das cabeças polares dos lipídios. A análise das propriedades estruturais da bicamada na vizinhança das espécies da Emodina como área por lipídio e densidade eletrônica dos lipídios, mostrou que o efeito da EM- na estrutura da bicamada lipídica é maior do que o da EMH. Esses resultados corroboram as nossas medidas de DSC(Differential Scanning Calorimetry) das espécies da Emodina na bicamada. / Emodin (EMH) is one of the most abundant anthraquinone derivatives found in nature. This molecule has been used widely as research material, due to its biological and pharmacological activities such as antiviral, anticancer, antifungal, digestive and antibacterial activities. It is known that Emodin in alkaline aqueous solution can undergo more than one deprotonation, leading to the specie EM- in the first deprotonation process. In this PhD thesis, we studied the structural and electronic properties of this molecule in several solvents and lipid bilayers, in order to characterize the properties related to UV-Vis absorption spectroscopy, reactivity and thermodynamics of this molecule in these environments. Performing quantum mechanics (QM) calculations for all possible deprotonation sites and tautomeric isomers of Emodin in vacuum and in water, we identified the sites of the first, second and third deprotonations. We calculated the pKa1 of Emodin in water and pK*a1 in methanol with free energy perturbation method, implemented in the Monte Carlo simulation, and with QM calculations, where the solvent was treated as a polarizable continuum medium. Our best values for pKa1 of Emodin in these solvents were 8.4±0.5 and 10.3±1.5, which are in very good agreement with the experimental values obtained in this thesis pKa1=8.0±0.2 and pK*a1=11.1±0.1, for water and methanol, respectively. Additionally, we performed molecular dynamics simulations of both species in fully hydrated lipid bilayers of DMPC to investigate at atomic detail the molecular mechanism of the interaction of these species with lipid membrane and its preferred positions in this amphiphilic environment. As results of these simulations, we obtained that both species of Emodin have a strong tendency to insert into the lipid bilayer, remaining near the glycerol group of DMPC. These results corroborate our measured absorption spectra of these species in the bilayer, which qualitatively showed that both species are within the bilayer, inserted in the lipid headgroup region. Our results also show that the effect of EM- specie in the lipid bilayer structure is stronger than the EMH, which corroborate our DSC(Differential Scanning Calorimetry) measurements.
4

Estudos teórico e experimental de propriedades estruturais e eletrônicas da molécula emodina em solvente e em bicamadas lipídicas / Theoretical and Experimental Studies of Structural and Electronic Properties of Emodin Molecule in Solvent and Lipid Bilayers

Antonio Rodrigues da Cunha 08 August 2014 (has links)
A Emodina (EMH) é uma das antraquinonas mais abundantes na natureza. Essa molécula vem sendo largamente usada como material de estudo científico por apresentar diversas atividades farmacológicas, tais como antiviral, antitumoral, antifungal, digestiva e outras. É conhecido que a Emodina em solução aquosa alcalina pode sofrer mais de um processo de desprotonação, apresentando-se na forma desprotonada, EM-, após a primeira desprotonação. Nesta tese de doutorado estudamos as propriedades estruturais e eletrônicas da molécula Emodina em meio solvente e em bicamadas lipídicas a fim de caracterizar as propriedades relacionadas à espectroscopia UV-Vis, à reatividade e à termodinâmica dessa molécula nesses ambientes. Realizamos cálculos quânticos com a Emodina em vácuo e em meio solvente, onde consideramos todos os possíveis sítios de desprotonação. Como resultados desses cálculos, identificamos os sítios da primeira, segunda e terceira desprotonação. Calculamos o pKa1 da Emodina em água e o pK*a1 em metanol através de simulações computacionais com o método Monte Carlo e cálculos quânticos, com o solvente descrito com o modelo contínuo polarizável. Nossos melhores valores para o pKa1 da Emodina determinados nesses solventes foram 8.4±0.5 e 10.3±1.5, que estão em boa concordância com os valores experimentais, (pKa1=8.0±0.2 e pK*a1=11.1±0.1) obtidos nesta tese para Emodina em água e metanol, respectivamente. Adicionalmente realizamos simulações com Dinâmica Molecular com as espécies EMH e EM- em bicamada lipídica de DMPC, para investigar a nível atômico as interações dessas espécies com a bicamada e determinar as posições preferenciais dessas espécies nesse ambiente anfifílico. Os resultados dessas simulações mostraram que as espécies EMH e EM- ficam inseridas na bicamada, na região polar dos lipídios, próximos aos gliceróis. Esses resultados corroboram as nossas medidas do espectro de absorção dessas espécies em bicamada lipídica, onde mostramos de forma qualitativa, que ambas as espécies ficam inseridas na bicamada, na região das cabeças polares dos lipídios. A análise das propriedades estruturais da bicamada na vizinhança das espécies da Emodina como área por lipídio e densidade eletrônica dos lipídios, mostrou que o efeito da EM- na estrutura da bicamada lipídica é maior do que o da EMH. Esses resultados corroboram as nossas medidas de DSC(Differential Scanning Calorimetry) das espécies da Emodina na bicamada. / Emodin (EMH) is one of the most abundant anthraquinone derivatives found in nature. This molecule has been used widely as research material, due to its biological and pharmacological activities such as antiviral, anticancer, antifungal, digestive and antibacterial activities. It is known that Emodin in alkaline aqueous solution can undergo more than one deprotonation, leading to the specie EM- in the first deprotonation process. In this PhD thesis, we studied the structural and electronic properties of this molecule in several solvents and lipid bilayers, in order to characterize the properties related to UV-Vis absorption spectroscopy, reactivity and thermodynamics of this molecule in these environments. Performing quantum mechanics (QM) calculations for all possible deprotonation sites and tautomeric isomers of Emodin in vacuum and in water, we identified the sites of the first, second and third deprotonations. We calculated the pKa1 of Emodin in water and pK*a1 in methanol with free energy perturbation method, implemented in the Monte Carlo simulation, and with QM calculations, where the solvent was treated as a polarizable continuum medium. Our best values for pKa1 of Emodin in these solvents were 8.4±0.5 and 10.3±1.5, which are in very good agreement with the experimental values obtained in this thesis pKa1=8.0±0.2 and pK*a1=11.1±0.1, for water and methanol, respectively. Additionally, we performed molecular dynamics simulations of both species in fully hydrated lipid bilayers of DMPC to investigate at atomic detail the molecular mechanism of the interaction of these species with lipid membrane and its preferred positions in this amphiphilic environment. As results of these simulations, we obtained that both species of Emodin have a strong tendency to insert into the lipid bilayer, remaining near the glycerol group of DMPC. These results corroborate our measured absorption spectra of these species in the bilayer, which qualitatively showed that both species are within the bilayer, inserted in the lipid headgroup region. Our results also show that the effect of EM- specie in the lipid bilayer structure is stronger than the EMH, which corroborate our DSC(Differential Scanning Calorimetry) measurements.

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