Global ETD Search

91	Proton-Coupled Electron Transfer from Hydrogen-Bonded Phenols Irebo, Tania January 2010 (has links) Proton-coupled electron transfer (PCET) is one of the elementary reactions occurring in many chemical and biological systems, such as photosystem II where the oxidation of tyrosine (TyrZ) is coupled to deprotonation of the phenolic proton. This reaction is here modelled by the oxidation of a phenol covalently linked to a Ru(bpy)32+-moitey, which is photo-oxidized by a laser flash-quench method. This model system is unusual as mechanism of PCET is studied in a unimolecular system in water solution. Here we address the question how the nature of the proton accepting base and its hydrogen bond to phenol influence the PCET reaction. In the first part we investigate the effect of an internal hydrogen bond PCET from. Two similar phenols are compared. For both these the proton accepting base is a carboxylate group linked to the phenol on the ortho-position directly or via a methylene group. On the basis of kinetic and thermodynamic arguments it is suggested that the PCET from these occurs via a concerted electron proton transfer (CEP). Moreover, numerical modelling of the kinetic data provides an in-depth analysis of this CEP reaction, including promoting vibrations along the O–H–O coordinate that are required to explain the data. The second part describes the study on oxidation of phenol where either water or an external base the proton acceptor. The pH-dependence of the kinetics reveals four mechanistic regions for PCET within the same molecule when water is the base. It is shown that the competition between the mechanisms can be tuned by the strength of the oxidant. Moreover, these studies reveal the conditions that may favour a buffer-assisted PCET over that with deprotonation to water solution. Proton-coupled electron transfer phenol oxidation hydrogen bonds artificial photosynthesis promoting vibrations proton transfer laser flash-quench transient absorption. Physical chemistry Fysikalisk kemi
92	Nitric Oxide Reductase from Paracoccus denitrificans : A Proton Transfer Pathway from the “Wrong” Side Flock, Ulrika January 2008 (has links) Denitrification is an anaerobic process performed by several soil bacteria as an alternative to aerobic respiration. A key-step in denitrification (the N-N-bond is made) is catalyzed by nitric oxide reductase (NOR); 2NO + 2e- + 2H+ → N2O + H2O. NOR from Paracoccus denitrificans is a member of the heme copper oxidase superfamily (HCuOs), where the mitochondrial cytochrome c oxidase is the classical example. NOR is situated in the cytoplasmic membrane and can, as a side reaction, catalyze the reduction of oxygen to water. NORs have properties that make them divergent members of the HCuOs; the reactions they catalyze are not electrogenic and they do not pump protons. They also have five strictly conserved glutamates in their catalytic subunit (NorB) that are not conserved in the ‘classical’ HCuOs. It has been asked whether the protons used in the reaction really come from the periplasm and if so how do the protons proceed through the protein into the catalytic site? In order to find out whether the protons are taken from the periplasm or the cytoplasm and in order to pinpoint the proton-route in NorB, we studied electron- and proton transfer during a single- as well as multiple turnovers, using time resolved optical spectroscopy. Wild type NOR and several variants of the five conserved glutamates were investigated in their solubilised form or/and reconstituted into vesicles. The results demonstrate that protons needed for the reaction indeed are taken from the periplasm and that all but one of the conserved glutamates are crucial for the oxidative phase of the reaction that is limited by proton uptake to the active site. In this thesis it is proposed, using a model of NorB, that two of the glutamates are located at the entrance of the proton pathway which also contains two of the other glutamates close to the active site. denitrification nitric oxide reductase heme copper oxidase superfamily divergent member proton transfer electron transfer single turnover spectroscopy periplasm glutamate proton pathway Biochemistry Biokemi
93	Aplinkos poveikis fotoindukuotiems reiškiniams organinėse molekulėse / Environmental effects on photoinduced processes in organic molecules Mačernis, Mindaugas 07 March 2011 (has links) Disertacijoje nagrinėjamas galimas aplinkos poveikis organinių molekulių elektroninių būsenų savybėms. Tam tikslui yra naudojami kompiuterizuotieji kvantinės mechanikos metodai, kuriais remiantis nagrinėjamos įvairių molekulių savybės. Ištirtos 2-(N-metil-α-iminoethyl)-fenol ir N-triphenylmethylsalicylidene imine molekelulių, esančių poliniame tirpiklyje, struktūros pagrindinėje ir sužadintose elektroninėse būsenose. Pirmą kartą parodyta, kad, norint gauti teisingą kokybinį ir artimą kiekybiniam vidujmolekulinės protono pernašos potencinės energijos paviršių, būtina atsižvelgti į polinių tirpiklio molekulių kuriamą vandenilinių ryšių tinklą bei į nulinių svyravimų energijas. Pastarieji ir nulemia protono pernašos vyksmo kryptį bei efektyvumą. Parodyta, kad anilų klasės molekulių konformerų susiformavimas priklauso nuo tirpiklio poliškumo, o jų susidarymas savo ruožtu konkuruoja su klasterių iš tirpiklio molekulių susiformavimo galimybėmis. Pirmą kartą parodyta, kad dipolinio momento vertė bakteriorodopsine yra nulemta membranos paviršiuose esančių radikalų. Pademonstruota, kad stilbazolio molekulė deformuojasi ir sudaro naujus konformerus (pademonstruota dviejų formų atsiradimo galimybė) tik esant molekulėms tirpalo apsuptyje. Šis rezultatas paaiškino eksperimente stebimus skirtuminių spektrinių pokyčių evoliucijos prigimtį. Apskaičiuotos ir išanalizuotos karotinoidų - luteino, violaksantino ir zeaksantino molekulių - žemiausios sužadintos elektroninės būsenos. Parodyta... [toliau žr. visą tekstą] / To explore changes caused by the environment on the internal characteristics of an organic molecule is the objective of the thesis. For this purpose we investigate a variety of organic molecules. Using various methods of quantum mechanics calculations possible influence of a polar solvent on the ground and excited states of 2-(N-metil-α-iminoethyl)-fenol and N-triphenylmethylsalicylidene imine is considered. It is shown for the first time that in order to obtain the correct qualitative and quantitative interpretation of possible pathways of the intermolecular proton transfer the hydrogen network of the polar solvent molecules together with the zero point energy have to be taken into consideration. It is also shown that conformational variability of anil-type molecules in polar solvents is competing with clusters formation of solvent molecules. It is shown for the first time that the dipole moment of bacteriorhodopsin is mainly defined by cytoplasmic and extracellular coils on the surfaces of the membrane. It is also demonstrated that the stilbazole molecule experiences the deformation resulting in formation of new conformers (at least two forms are present) in the solvent surrounding. The experimental data of the transient spectroscopy were explained in the basis of these model calculations. The lowest excited states of carotinoids, such as lutein, zeaxanthin and violoxantin are calculated and analyzed. Sensitivity of the excited electronic state on the polar environment is... [to full text] Physics Šifo bazė Protono pernaša Karotinoidai Potencinės energijos paviršius Schiff base Proton transfer Potential energy surfaces Carotenoids
94	Aplinkos poveikis fotoindukuotiems reiškiniams organinėse molekulėse / Environmental effects on photoinduced processes in organic molecules Mačernis, Mindaugas 07 March 2011 (has links) Disertacijoje nagrinėjamas galimas aplinkos poveikis organinių molekulių elektroninių būsenų savybėms. Tam tikslui yra naudojami kompiuterizuotieji kvantinės mechanikos metodai, kuriais remiantis nagrinėjamos įvairių molekulių savybės. Ištirtos 2-(N-metil-α-iminoethyl)-fenol ir N-triphenylmethylsalicylidene imine molekelulių, esančių poliniame tirpiklyje, struktūros pagrindinėje ir sužadintose elektroninėse būsenose. Pirmą kartą parodyta, kad, norint gauti teisingą kokybinį ir artimą kiekybiniam vidujmolekulinės protono pernašos potencinės energijos paviršių, būtina atsižvelgti į polinių tirpiklio molekulių kuriamą vandenilinių ryšių tinklą bei į nulinių svyravimų energijas. Pastarieji ir nulemia protono pernašos vyksmo kryptį bei efektyvumą. Parodyta, kad anilų klasės molekulių konformerų susiformavimas priklauso nuo tirpiklio poliškumo, o jų susidarymas savo ruožtu konkuruoja su klasterių iš tirpiklio molekulių susiformavimo galimybėmis. Pirmą kartą parodyta, kad dipolinio momento vertė bakteriorodopsine yra nulemta membranos paviršiuose esančių radikalų. Pademonstruota, kad stilbazolio molekulė deformuojasi ir sudaro naujus konformerus (pademonstruota dviejų formų atsiradimo galimybė) tik esant molekulėms tirpalo apsuptyje. Šis rezultatas paaiškino eksperimente stebimus skirtuminių spektrinių pokyčių evoliucijos prigimtį. Apskaičiuotos ir išanalizuotos karotinoidų - luteino, violaksantino ir zeaksantino molekulių - žemiausios sužadintos elektroninės būsenos. Parodyta... [toliau žr. visą tekstą] / To explore changes caused by the environment on the internal characteristics of an organic molecule is the objective of the thesis. For this purpose we investigate a variety of organic molecules. Using various methods of quantum mechanics calculations possible influence of a polar solvent on the ground and excited states of 2-(N-metil-α-iminoethyl)-fenol and N-triphenylmethylsalicylidene imine is considered. It is shown for the first time that in order to obtain the correct qualitative and quantitative interpretation of possible pathways of the intermolecular proton transfer the hydrogen network of the polar solvent molecules together with the zero point energy have to be taken into consideration. It is also shown that conformational variability of anil-type molecules in polar solvents is competing with clusters formation of solvent molecules. It is shown for the first time that the dipole moment of bacteriorhodopsin is mainly defined by cytoplasmic and extracellular coils on the surfaces of the membrane. It is also demonstrated that the stilbazole molecule experiences the deformation resulting in formation of new conformers (at least two forms are present) in the solvent surrounding. The experimental data of the transient spectroscopy were explained in the basis of these model calculations. The lowest excited states of carotinoids, such as lutein, zeaxanthin and violoxantin are calculated and analyzed. Sensitivity of the excited electronic state on the polar environment is... [to full text] Physics Šifo bazė Protono pernaša Karotinoidai Potencinės energijos paviršius Schiff base Proton transfer Potential energy surfaces Carotenoids
95	Proton-coupled electron transfer and tyrosine D of phototsystem II Jenson, David L. Jenson 11 August 2009 (has links) EPR spectroscopy and isotopic substitution were used to gain increased knowledge about the proton-coupled electron transfer (PCET) mechanism for the reduction of the tyrosine D radical (YD) in photosystem II. pL dependence (where pL is either pH or pD) of both the rate constant and kinetic isotope effect (KIE) was examined for YD reduction. Second, the manner in which protons are transferred during the rate-limiting step for YD* reduction at alkaline pL was determined. Finally, high field electron paramagnetic resonance (EPR) spectroscopy was used to study the effect of pH on the environment surrounding both the tyrosine D radical and the tyrosine Z radical (YZ). At alkaline pL, it was determined that the proton and electron are both transferred in the rate-limiting step of YD reduction. At acidic pL, the proton transfer occurs first followed by electron transfer. Proton inventory experiments indicate that there is more than one proton donation pathway available to YD* during PCET reduction at alkaline pL. Additionally, the proton inventory experiments indicate that at least one of those pathways is multiproton. High field EPR experiments indicate that both YD* and YZ* are hydrogen bonded to neutral species. The EPR gx component for YD* is invariant with respect to pH. Analysis of the EPR gx component for Yz* indicates that its environment becomes more electropositive as the pH is increased. This is most likely due to changes in the hydrogen bond strength Photosynthesis Photosystem II Proton inventory Tyrosine Proton coupled electron transfer Kinetic isotope effect Histidine Proton transfer reactions Oxidation-reduction reaction Tyrosine
96	Etude du transfert de protons dans les systèmes moléculaires / Proton transfer along molecular wires Esteves López, Natalia 06 July 2017 (has links) Une des meilleures sources d’énergie verte serait d’être capable de casser une molécule d’eau à partir du rayonnement visible fourni par le soleil, afin de générer du H$_2$. L’eau présente le don d’ubiquité sur terre puisqu’elle est présente, sous ses trois phases, dans les océans, la terre et l’atmosphère. Cependant, une énergie de 6.66 eV (VUV) est nécessaire pour rompre directement une des liaisons covalentes de l’eau. Dans ce travail, nous montrons qu’il est possible de dissocier l’eau si celle-ci est associée à un catalyseur photosensible de nature organique, dont les prototypes absorbent dans l’UV, comme la Pyridine (Py). Un récent travail théorique prédit que la Py peut jouer le rôle de ce photocatalyseur, suivant la réaction : Py-H$_2$O + h$\nu_1 \to$ Py-H$_2$O $\to$ PyH$\bullet$ + OH$\bullet$Pour tester ce modèle théorique nous avons étudié le complexe Py-eau isolé dans un cluster moléculaire froid. Nous avons caractérisé la spectroscopie électronique du PyH$\bullet$ en phase gazeuse et nous avons mis en évidence cette réaction de photodissociation par irradiation UV de clusters Py-(H$_2$O)$_n$. Nous avons aussi testé ce système en matrices cryogéniques pour évaluer l’effet de la solvatation solide. La dernière étape du processus, la régénération du photocatalyseur par absorption d’un deuxième photon UV (PyH$\bullet$ + h$\nu \to$ Py + H$\bullet$) à été aussi prouvé. Il semblerait que seuls les radicaux PyH$\bullet$ chauds soient capables d’engendrer cette dernière réaction.A l’heure actuelle, nous explorons de nouveaux systèmes moléculaires prototypes susceptibles de conduire au même phénomène. / A major challenge to generate green energy from sunlight would be to split water which is a ubiquitous molecule to produce H$_2$. However VUV light (6.66 eV) is needed to dissociate the H-OH covalent bond. In this work we will show that it is possible to dissociate water via photo-sensitisation with UVC light, using a simple organic catalyst.Recently, ab-initio calculations predict that pyridine (Py) can act as a photo-catalyst to split water by absorption of a UV photon, following the reaction:Py-H$_2$O + h$\nu_1 \to$ Py-H$_2$O $\to$ PyH$\bullet$ + OH$\bullet$ To test this prediction, we studied the Py-H$_2$O complex in isolated cold molecular cluster and the system trapped in cryogenic matrices. We characterized the electronic spectroscopy of the PyH$\bullet$ in the gas phase and we evidenced the reaction through UV excitation of Py-(H$_2$O) $_n$ clusters. We have evidenced that the reaction leads PyH$\bullet$ as photoproduct of the reaction. We also evidenced that the surrounding conditions play an important role in the reaction.We have demonstrated that the UV excitation of Py-water clusters leads to the formation of PyH$\bullet$, thus we have evidenced the water splitting reaction. The last step of the process, that is the regeneration of the catalyst by absorption of a second UV photon (PyH$\bullet$ + h$\nu \to$ Py + H$\bullet$) has been studied and it seems that only hot PyH$\bullet$ molecules are able to follow this channel. In the present, we are studying other aromatic molecules which are expected to lead the photochemical dissociation of water. Transfert de protons Phase gazeuse Matrices cryogéniques Spectroscopie IR et UV-Visible Jet supersonique Proton transfer Gas phase Cryogenic matrices Spectroscopy IR and UV-Visible Supersonic jet
97	Estudo da complexação da fisetina com ciclodextrinas / Study of the Complexation of Fisetin with Cyclodextrins Mariana Rizzi Guzzo 15 March 2007 (has links) Neste trabalho de Mestrado, foram feitos estudos do comportamento fotofísico da fisetina em diversos solventes através de medidas de absorção de luz UV-Visível, fluorescência estática e resolvida no tempo e da interação entre fisetina (3,3\',4\',7-tetrahidroxiflavona) e 7-hidroxiflavona com ciclodextrinas ( beta e gama) (CDs) através de experimentos de absorção de luz UV-Visível, sinal induzido de dicroísmo circular, fluorescência estática e resolvida no tempo, anisotropia de estado estacionário e RMN de 1H, focando a dependência destas medidas em função da temperatura e do pH. Os resultados experimentais foram comparados com estudos mecânico-quânticos baseados no modelo semi-empírico SAM1 (AMPAC), e nos funcionais B3LYP e MPW1PW91, da Teoria do Funcional de Densidade, empregando os conjuntos de funções de base 6-311G* e 3-21G*. Os estudos da fisetina em diferentes solventes próticos e apróticos mostraram que a fluorescência da sonda é fortemente dependente do solvente. Resultados experimentais indicam a formação de complexos de inclusão entre as CDs e os flavonóides acima. A fisetina com ?-CD forma complexo de estequiometria 1:1 nos meios neutro/ácido e básico, cujos valores de constante de complexação são 900 +- 100 +_ 240 +_ 90 (L/mol), respectivamente. Os dados teóricos evidenciaram que a inclusão da fisetina na beta-CD ocorre preferencialmente pelo anel fenila. O complexo com a gama-CD apresenta estequiometria de 1:1 em meio ácido/neutro e de 1:2 em meio básico, com constantes de complexação de 94 +- 30 e 130 +- 10 (L/mol), respectivamente. Os estudos com a 7-hidroxiflavona revelaram que somente ocorre a formação de complexos com a beta-CD de estequiometria 1:1 e não há dependência do pH. As constantes de complexação obtidas nos meios ácido/neutro e básico são similares, 1430 +-- 510 e 1220 +- 165 L/mol, respectivamente. / In this work, the photophysics of fisetin (3,3\',4\',7-tetrahydroxyflavone) in several solvents was studied through UV-vis absorption spectra, steady-state and time-resolved fluorescence measurements. The interaction between fisetin and 7-hydroxyflavone and cyclodextrins (b- e g-) (CDs) was also investigated by UV-vis absorption spectra, induced signal of circular dichroism, steady-state and time-resolved fluorescence, steady-state anisotropy, and 1H NMR, with dependence on pH and temperature. Some experimental data were compared with quantum-mechanics studies based on the SAM1 (AMPAC) semi-empirical model, as well as with the B3LYP and MPW1PW91 functional models from the Density Functional Theory using the 6-311G and 3-21G* basis sets. The study of the photophysics of fisetin in protic and aprotic solvents showed a complex behavior and a strong dependence on the solvent. The occurrence of many equilibria between the possible structures of fisetin, e.g. the normal, a few deprotonated ones, and the tautomer due to the excited state intramolecular proton transfer can be responsible for the complex analyses of these experimental data. The spectroscopic measurements show that, at pH 4.0 and 6.5, the complex fisetin - b-CD is formed in a Fis:b-CD 1:1 stoichiometry and an equilibrium constant (K) of 900 ± 100 L/mol. In basic medium (pH 11.5), K decreases to 240 ± 90 L/mol. Molecular modeling points out that the inclusion complex is formed preferentially via entry of the fisetin phenyl group into b-CD. On the other hand, the fisetin - g-CD has a stoichiometry of 1:1 in acid/neutral solutions and of 1:2 in basic conditions. The K values are 94 ± 30 e 130 ± 10 (L/mol), respectively. The 7-hydroxyflavone can only form inclusion complexes with b-CD. The stoichiometry is 1:1 and there is no dependence on pH. Both equilibrium constants determined either in acid or basic medium is very similar to each other, 1430 ± 510, and 1220 ± 165 L/mol, respectively. For this reason, we suppose that the inclusion of this compound into b-CD is also through the phenyl ring of the flavonoid. Ciclodextrinas Flavonóides circular dichroism cyclodextrin Fisetin fluorescence NMR pH effect quantum mechanics
98	Étude de propriétés photophysiques de protéines fluorescentes par dynamique moléculaire / Study of photophysical properties of fluorescent proteins by molecular dynamics Verdiere, Jérémy 19 December 2016 (has links) Les protéines fluorescentes sont très largement utilisées dans les études de biologie moléculaire depuis maintenant une vingtaine d’année. Pour autant, l’origine de leurs propriétés photophysiques n’est pas totalement élucidée. Dans cette thèse, nous avons essayé d’améliorer la compréhension de la photophysique de deux protéines fluorescentes particulières : Padron et EosFP.Dans la protéine Padron, nous avons étudié l’isomérisation du chromophore et cherché à déterminer si la protonation et l’isomérisation sont simultanées ou successives. Pendant l’isomérisation, le donneur de proton potentiel est le résidu Tyr159. Nous avons d’abord montré que dans le vide, le transfert de proton est peu probable quelle que soit la géométrie du chromophore. Dans la protéine (où l’effet de l’environnement n’est pas négligeable) nous avons mis en évidence par dynamique moléculaire que, durant l’isomérisation, le transfert de proton n’est presque jamais favorable et reste donc un marginal.Par ailleurs, ces mêmes dynamiques ont montré que, à la fin de l’isomérisation, il apparaît de nombreux chemins de molécules d’eau reliant le chromophore au solvant et pouvant permettre un transfert de proton. On conclut doncque l’isomérisation et la protonation ne sont pas simultanées mais successives.Dans le cas de la protéine EosFP, nous avons analysé l’effet d’une molécule d’eau présente dans une partie des structures cristallines. Les dynamiques avec le chromophore à l’état fondamental ont montré que cette molécule ne joue pas de rôle, que ce soit sur le réseau de liaison hydrogène ou sur le spectre d’absorption. Par contre, à l’état excité, les dynamiques ont montré que l’extinction de fluorescence est beaucoup plus rapide sans la molécule d’eau qu’en sa présence.Par ailleurs, ces dynamiques ont mis en évidence que la protéine bloque souvent le chromophore dans des géométries où il ne peut pas retourner à l’état fondamental ni par fluorescence, ni par conversion interne. Ces géométries « noires» jouent un rôle important dans la photophysique.Pour tenir compte de ces géométries, nous avons calculé le rendement quantique et le temps de vie de fluorescence par intégration directe le long des trajectoires et par cinétique chimique. Dans les deux cas, nous avons obtenu un accord qualitatif avec l’expérience. / Fluorescent proteins are widely used in biology studies since 20 years. Yet, the origin of their photophysical properties aren’t totally explained. Here, we try to improve the understanding of two particular fluorescent proteins: Padron and EosFP.In the protein Padron, we work on the isomerization of chromophore and try to determine whether isomerization and protonation are simultaneous or successive processes. During the isomerization, the potential donor is Tyr159.First, we show that, in vacuum, the proton transfer is quite unlikely whatever the chromophore geometry.In the protein (where the environment effect isn’t negligible) we evidence with molecular dynamics that, during isomerization, proton transfer stays marginal.In addition, these dynamics shown the appearance, at the end of isomerization, of a lot of water molecules channel between the chromophore and the solvent allowing a proton transfer. We conclude that isomerization and protonation are successive processes.In the case of the protein EosFP, we first analyze the effect of a water molecule which is found only in some of the crystallographic structures.Molecular dynamics of the protein with the chromophore in the ground state show that the water molecule doesn’t play any role neither in the hydrogen bond network nor in the absorption spectra.On the contrary, in the excited state, dynamics without this water show a significant faster decay of fluorescence that those with the molecule.In addition, those dynamics have demonstrate that during long period, the protein retains the chromophore in geometries in which it is unable to convert to the ground state, neither by fluorescence nor by internal conversion. Those “dark” geometries play a crucial role in the photophysics.To take them into account, we calculate the quantum yield and the fluorescence lifetime by direct integration along trajectories and by a kinetic scheme. We obtain a good qualitative agreement with the two methods. Proteine fluorescente Liaison hydrogène Transfert de proton Spectre d'absorption Declin de fluorescence Dynamique moléculaire Fluorescent protein Hydrogen Bond Proton transfer Absorption spectra Fluorescence decay Molecular dynamics
99	Časově rozlišená fluorescence ve výzkumu interakcí hyaluronanu a koloidních systémů / Time-Resolved Fluorescence in Research of Hyaluronan-Colloidal Systems Interactions Mondek, Jakub January 2018 (has links) The aim of the doctoral thesis was to study advanced fluorescence techniques and its use in colloids or hyaluronan-surfactant systems and hydrogels based on hyaluronan, respectively. Steady-state and time-resolved fluorescence were used to study excited state proton transfer fluroescen probes in hyaluronan-surfactant systems to asses the influence of hyaluronan hydration to its interactions with oppositely charged surfactants. Firstly, different excited state proton transfer fluorescence probes were discussed to choose the most suitable candidate for next research. The influence of hyaluronan on inner environment of micells was determined based on the sensitivity of excited state proton transfer of chosen fluorescence probe 1-naphtol and, based on above mentioned experiments, the structure of hyaluronan hydration shell was discussed. The next part of doctoral thesis was focused on fluorescence lifetime correlation spectroscopy and on the development of method of nanorheology. Measured correlation functions were transformed to mean square displacement with developed MATLAB script. Firstly, the fluorescence method was compared with well described methods such as videomicrorheology and dynamic light scattering to asses the reliability of fluorescence correlation spectroscopy in microrheology. Secondly, nanorheology method was developed and its use in passive nanorheology of hyaluronan hydrogels was discussed. Based on mentioned experiments, the fluorescence correlation spectroscopy microrheology and nanorheology methods were optimized to use the methods in hydrogel research.
100	Développement de champs de forces polarisables et applications à la spectroscopie vibrationnelle / Development of polarizable force fields and applications in vibrational spectroscpy Thaunay, Florian 02 September 2016 (has links) La spectroscopie de dissociation par absorption de photons infrarouges (IRPD) permet d’obtenir les signatures vibrationnelles d’espèces chargées en phase gazeuse, telles que de petits peptides ou des ions hydratés dans des agrégats d’eau. L’attribution des modes de vibration pour établir une relation entre le spectre expérimental et une structure moléculaire est une tâche délicate et nécessite le recours à la modélisation moléculaire.Ce manuscrit présente un ensemble d’outils théoriques pour le calcul et l’attribution de spectres vibrationnels, basée principalement sur la dynamique moléculaire classique et le champ de forces polarisable AMOEBA, ainsi que son application à des ions gazeux de tailles diverses. Les ions hydratés dans des agrégats d’eau M(H2O)n (n allant de 6 à 100) sont caractérisés par une dynamique importante, et leur spectre expérimental ne peut pas être décrit par une seule structure. La signature des peptides évolue avec la température et les effets d’anharmonicité dynamique. Ils peuvent également être le siège de mécanismes de transfert de proton, présentant une signature vibrationnelle très caractéristique.La surface d’énergie potentielle de ces systèmes est explorée par la dynamique moléculaire classique en trajectoires individuelles ou avec échange de répliques, afin d’engendrer des structures énergétiquement stables. Pour les plus petits systèmes, les méthodes quantiques DFT et post-HF sont utilisées pour confirmer les structures de plus basse énergie, calculer leurs spectres IR statiques et proposer des attributions des modes de vibration. Pour les plus systèmes de plus grandes tailles, c’est-à-dire les ions dans des gouttes d’eau de plusieurs dizaines de molécules, la simulation des spectres IR à température finie est basée sur la transformée de Fourier de la fonction d’autocorrélation du moment dipolaire (DACF), calculée pour une trajectoire de dynamique moléculaire classique. Cette méthode n’offrant pas d’accès direct aux modes normaux de vibration, nous avons implémenté une méthode d’attribution dynamique, basée sur la Driven Molecular Dynamics (DMD) et couplée au DACF. La combinaison AMOEBA/DACF/DMD a été utilisée pour reproduire et attribuer le spectre du dipeptide Ace-Phe-Ala-NH2, et ceux d’ions hydratés dans des agrégats d’eau.Enfin, la signature vibrationnelle d’un transfert de proton ne peut être décrite, ni par des méthodes statiques quantiques, ni par la dynamique classique. Sa modélisation a nécessité le développement d’un modèle Empirical Valence Bond (EVB) à deux états, couplé au champ de forces polarisable AMOEBA. Le modèle EVB a été implémenté dans la suite logicielle Tinker. Il permet de reproduire le comportement dynamique du transfert de proton au sein de petits peptides et de diacides déprotonés, ainsi que la signature spectroscopique observée expérimentalement.Une partie importante des applications de ces développements concerne des ions simples hydratés dans des nano-gouttelettes, et en particulier l’ion sulfate de grande importance environnementale. Nous avons pu reproduire de façon satisfaisante, pour la première fois, les spectres d’agrégats contenant jusqu’à 100 molécules d’eau. Le principal contributeur à cette spectroscopie expérimentale est l’équipe d’E. Williams à l’université de Californie à Berkeley. Nous avons établi avec eux une collaboration pour compléter ce travail en modélisant les spectres IR d’ions sulfates hydratés [SO4(H2O)n=9-36]2-, dont ils ont obtenu les signatures expérimentales. / Spectroscopy dissociation by absorption of infrared photons (IRPD) provides vibrational signatures of charged species in the gas phase, such as small peptides or hydrated ions in water clusters. The vibrational normal modes assignment to establish a relationship between the experimental spectrum and molecular structure is a delicate task and requires the use of molecular modeling.This manuscript presents a set of theoretical tools for calculation and assignment of vibrational spectra, based mainly on classical molecular dynamics and polarizable AMOEBA force field, and its application to gaseous ions of various sizes. Hydrated ions in water clusters M(H2O)n (n in 6-100 range) are characterized by a dynamic behavior, and their experimental spectrum can not be described by a single structure. The signature of peptides changes with temperature and dynamic anharmonicity effects. They can also be the site of proton transfer mechanisms, with a very characteristic vibrational signature.The potential energy surface of these systems is explored by classical molecular dynamics in individual trajectories or replica exchange to generate energetically stable structures. For smaller systems, quantum methods, as DFT and post-HF, are used to confirm the lowest energy structures, calculate their static IR and propose normal modes assignments. For larger systems, i.e ions in water drops of several tens of molecules, the simulation of IR spectra at finite temperature is based on the Fourier transform of the autocorrelation function of the dipole moment (DACF), calculated during a classical molecular dynamics trajectory. As this method does not allow direct access to the vibrational normal modes, we implemented a method of dynamic assigments, based on the Driven Molecular Dynamics (DMD) and coupled to the DACF. The combination AMOEBA /DACF / DMD was used to reproduce and assign the spectrum of the dipeptide Ace-Phe-Ala-NH2, and those of hydrated ions in water clusters.Finally, the vibrational signature of a proton transfer can not be described by quantum static methods or by classical dynamics. Its modeling required the development of a two states Empirical Valence Bond Model (EVB), coupled with AMOEBA polarizable force field. The two states EVB model was implemented in the software TINKER. It can reproduce the dynamic behavior of proton transfer in small peptides and deprotonated acids, as well as the spectroscopic signatures observed experimentally.An important part of the applications of these developments relates simple hydrated ions in nano-droplets, and in particular the sulfate ion of great environmental importance. We were able to reproduce satisfactorily, for the first time, the spectra of clusters containing up to 100 water molecules. The main contributor to this experimental spectroscopy is the team of E. Williams from the University of California of Berkeley. We have established cooperation with them to complete this work by modeling the IR spectra of hydrated sulfates ions [SO4(H2O) n=9-36]2-, for which they obtained experimental signatures. Spectroscopie infrarouge Champs de forces polarisables Dynamique moléculaire Hydratation des ions Transfert de proton Modes normaux de vibration Infrared spectroscopy Polarizable force fields Molecular dynamics Ion hydration Proton transfer Vibrational normal modes

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