Global ETD Search

101	Model Development and Application of Molecular Simulations for the Study of Proton Transport in Bulk Water and for the Prediction of Dipole Moments of Organic Compounds Asthana, Abhishek 05 December 2012 (has links) (PDF) The present work demonstrates the application of molecular simulations (MD) in two different areas: proton transport in bulk water and estimation of the dipole moment of polar organic compounds. In both areas, relatively few successful and robust methodologies exist. In the first part, a new polarizable water model is developed for MD simulations of the proton transport process. The model was parametrized from a combination of quantum chemical calculations and experimental water properties. The model was implemented in MD simulation studies of liquid water at room temperature, as well as with excess protons. For pure water the model gave good agreement with experimental properties. The proton transport rate for a single excess proton also gave a good match with the experimental value. The water model was further extended to include chloride ions. At 0.2 M concentration the resulting density and structure agreed well with experiment, and the proton transport rate was found to be slightly reduced. The model was further extended to include multiple excess protons. For the second part of the project, an open source ab initio MD program, SIESTA, was used to perform simulations of several organic compounds which potentially have multiple stable conformations, to determine their average dipole moments. A series of methods was developed. The most robust method involved modifications to the SIESTA code and statistical analysis of the resulting configurations, in order to more accurately predict the average dipole moment. The resulting dipole moments were in good agreement with the experimental values for cases in which experimental values were reliable. Based on this study, a general method to estimate the average dipole moment of any compound is proposed. Molecular Dynamics Simulation water modeling ion electrolyte proton transfer dipole SIESTA dipole moment conformations ab initio molecular dynamics Gaussian Chemical Engineering
102	Proton-transfer Study of Unbound <sup>19</sup>Ne States via <sup>2</sup>H(<sup>18</sup>F,<i>α</i>+<sup>15</sup>O)<i>n</i> Reaction Adekola, Aderemi S. 23 April 2009 (has links) No description available. Nuclear Physics proton-transfer reaction proton width reaction rate astrophysical S-factor
103	Mécanismes de transfert de proton d’une réaction acido-basique en phase aqueuse : une étude ab-initio Rivard, Ugo 11 1900 (has links) Les réactions de transfert de proton se retrouvent abondamment dans la nature et sont des processus cruciaux dans plusieurs réactions chimiques et biologiques, qui se produisent souvent en milieu aqueux. Les mécanismes régissant ces échanges de protons sont complexes et encore mal compris, suscitant un intérêt des chercheurs en vue d’une meilleure compréhension fondamentale du processus de transfert. Le présent manuscrit présente une étude mécanistique portant sur une réaction de transfert de proton entre un acide (phénol fonctionnalisé) et une base (ion carboxylate) en phase aqueuse. Les résultats obtenus sont basés sur un grand nombre de simulations de dynamique moléculaire ab-initio réalisées pour des systèmes de type « donneur-pont-accepteur », où le pont se trouve à être une unique molécule d’eau, permettant ainsi l’élaboration d’un modèle cinétique détaillé pour le système étudié. La voie de transfert principalement observée est un processus ultra-rapide (moins d’une picoseconde) passant par la formation d’une structure de type « Eigen » (H9O4+) pour la molécule d’eau pontante, menant directement à la formation des produits. Une seconde structure de la molécule d’eau pontante est également observée, soit une configuration de type « Zündel » (H5O2+) impliquant l’accepteur de proton (l’ion carboxylate) qui semble agir comme un cul-de-sac pour la réaction de transfert de proton. / Proton transfer reactions are found abundantly in nature and are critical processes in several chemical and biological reactions, which often occur in aqueous medium. The mechanisms governing these proton exchanges are complex and poorly understood, sparking interest of researchers for a better fundamental understanding of the transfer process. This manuscript presents a mechanistic study for a proton transfer reaction between an acid (functionalized phenol) and a base (carboxylate ion) in aqueous phase. The results are based on a large number of Ab-initio molecular dynamics simulations performed for a “donor-bridge-acceptor” type of system, where the bridge is a single molecule of water, allowing the development of a detailed kinetic model for this system. The transfer channel mainly observed is an ultra-fast one (less than a picosecond), through the formation of a Eigen-like (H9O4+) structure for the bridging water molecule, leading directly to the formation of the products. A second structure of the bridging water molecule is also observed, which is a Zündel-like (H5O2+) configuration involving the proton acceptor (carboxylate ion), which seems to act as a dead-end for the proton transfer reaction. Transfert de proton Réactions acide-base Dynamique moléculaire ab-initio Transfert de charge Mécanisme réactionnel Intermédiaires Eigen et Zündel Proton transfer Acid-base reactions Ab-initio molecular dynamics Charge transfer Reaction mechanism Eigen and Zündel intermediates
104	Spektroskopische Charakterisierung der grün-absorbierenden Kanalrhodopsin-Chimäre ReaChR Krause, Benjamin Sören 06 September 2018 (has links) Kanalrhodopsine (ChRs) sind lichtgesteuerte Ionenkanäle, welche nach Absorption eines Photons durch den Retinal-Cofaktor einen passiven Ionentransport über die Zellmembran katalysieren. Im Zuge von optogenetischen Anwendungen wird diese Reaktion für die Beeinflussung der Ionenhomöostase von verschiedenen Zelltypen und Geweben ausgenutzt. Zu Beginn dieser Arbeit wurden lichtinduzierte Strukturänderungen und Protontransferschritte in einem breiten Zeitbereich (Nanosekunden bis Minuten) in dem grün-absorbierenden ChR ReaChR mithilfe von stationärer und transienter UV-vis- und Fourier-Transform-Infrarot-Spektroskopie (FTIR) untersucht. Auf Basis der experimentellen Daten wurde ein komplexes Photozyklus-Modell konzipiert. Anschließend wurde die IR-aktive, nichtkanonische Aminosäure p-Azido-L-phenylalanin (azF) mittels Stopp-Codon-Suppression ortsspezifisch an mehreren Positionen innerhalb der vermuteten ionenleitenden Kanalpore in ReaChR inkorporiert und mit FTIR untersucht. azF ist sensitiv gegenüber Polaritätsänderungen und absorbiert in einem hochfrequenten Bereich (~2100 cm-1). Aufgrund der großen spektralen Separation zu endogenen Proteinschwingungen (< 1800 cm-1) können globale Konformations- und lokale Hydratisierungsänderungen simultan detektiert werden. Die erhobenen Daten leisten einen wichtigen Beitrag zum Verständnis der Bildung einer temporären Wasserpore in ChRs und demonstrieren zum ersten Mal den erfolgreichen in-vivo-Einbau einer artifiziellen Aminosäure in mikrobielle Rhodopsine und dessen schwingungsspektroskopische Analyse. Die Methode bietet aufgrund ihrer hohen Ortsauflösung ein großes Potential für die Studie von Mikroumgebungen innerhalb komplexer Proteinensemble. / Channelrhodopsins (ChRs) are light-gated ion channels. Upon absorption of a photon, the retinal chromophore isomerizes and drives conformational changes within the protein, which lead to a passive ion transport across the cell membrane. This capability is used for optogenetic applications to manipulate ionic homeostasis of different cell types and entire organisms. Within the work, light-induced structural changes and proton transfer steps were studied in the green-absorbing ChR ReaChR in great detail by steady-state and transient UV-vis and Fourier transform infrared spectroscopy (FTIR). The data were merged into a complex photocycle model. Next, the IR-active, unnatural amino acid p-azido-L-phenylalanine (azF) was site-specifically introduced at several sites of the putative ion pore of ReaChR by stop codon suppression. azF is sensitive to polarity changes and absorbs in a clear spectral window lacking endogenous protein vibrations. Thus, FTIR measurements of labeled mutants report for global conformational changes (< 1800 cm-1) and local hydration changes (~2100 cm-1) simultaneously. The presented findings reveal crucial insights regarding formation of a transient water pore in ChRs and demonstrate the first report of the successful in-vivo incorporation of an artificial amino acid into a microbial rhodopsin and its subsequent spectroscopic investigation. Additionally, the so far unprecedented spatial resolution renders this methodology superior over conventional FTIR methods to study microenvironments within complex protein ensembles. Kanalrhodopsin Photozyklus Protontransferreaktionen UV-vis-Spektroskopie FTIR Unnatürliche Aminosäuren Stopp-Codon-Suppression channelrhodopsin photocycle proton transfer reactions UV-vis spectroscopy FTIR unnatural amino acids stop codon suppression 570 Biowissenschaften; Biologie WD 2800 WD 2200 WE 5460 WF 9746 ddc:570
105	Ultrafast charge transfer processes in solution Adamczyk, Katrin 05 August 2010 (has links) Die Reaktionspfade und Reaktionsdynamik photoinduzierter bimolekularer Ladungstransferreaktionen werden mit Hilfe der ultraschnellen polarisationsabhängigen UV-Pump/IR-Probe-Spektroskopie charakterisiert. Allgemein akzeptierte Modelle zur Beschreibung von bimolekularen Elektrontranserreaktionen nehmen an, dass Ladungstrennung in polaren Lösungsmitteln zu zwei Arten von Ionenpaaren führt, den lockeren (LIPs) und den engen Ionenpaaren (TIPs). TIPs und LIPs können durch die Beobachtung von Schwingungsmoden spektroskopisch unterschieden werden. Allerdings deuten die multiplen Zeitskalen sowohl für die Bildung von TIPs als auch LIPs darauf hin, dass eine Unterscheidung in zwei Arten von Ionenpaaren mit definierter Geometrie eine erhebliche Vereinfachung ist. TIPs und LIPs sind vielmehr als Grenzfälle zu betrachten, zwischen derer eine kontinuierliche Verteilung verschiedener Ionenpaare existiert. Die Natur der Ionenpaare wird durch die Verteilung der neutralen Reaktionspaare vor Initiation der Reaktion bestimmt. Außerdem wird gezeigt, dass TIPs höchst anisotrop sind. Die Wichtigkeit der beidseitigen Orientierung der Reaktanten wird dabei offengelegt. Weiterhin wird erstmalig ein femtosekundenspektroskopischer Beweis für die Existenz von Kohlensäure in wäßriger Lösung präsentiert. Eine Photosäure wurde verwendet, um die ultraschnelle Protonierung von Bikarbonat optisch auszulösen. Kohlensäure wurde bisher als Feststoff in Eismatrizen und in der Gasphase detektiert. Da Kohlensäure als Intermediat zwischen Kohlenstoffdioxid und Bikarbonat postuliert wird, ist ihre Charakterisierung von immenser Bedeutung für das Verständnis grundlegender Säure-Base Chemie von Karbonaten in wäßriger Lösung. Die Analyse der zeitabhängigen Signale unter Verwendung eines theoretischen Modells erlaubt die Bestimmung der bimolekularen Reaktionsdynamik. Dies ermöglicht einen Einblick in die Säure-Base Chemie von Kohlensäure. / The reaction pathways and dynamics of photoinduced bimolecular charge transfer reactions are characterised with ultrafast polarisation-sensitive UV-pump/IR-probe-spectroscopy. Generally accepted models for bimolecular electron transfer reactions suppose that charge separation in polar solvents leads to two geminate ion pairs, namely loose (LIPs) and tight ion pairs (TIPs). By monitoring vibrational marker modes TIPs and LIPs can be distinguished spectroscopically. However, multiple time scales for the formation of TIPs and LIPs indicate that a distinction between two kinds of ion pairs with well-defined geometries is a considerable simplification. TIPs and LIPs should rather be regarded as limiting cases, as there is a continuous distribution of different ion pairs between these two limits. The crucial parameter governing the nature of the ion pairs is the distribution of neutral reaction pairs subsequent to initiation of the reaction. Furthermore, TIPs are found to be highly anisotropic, revealing the importance of mutual orientation of the reactants. This thesis also presents for the first time femtosecond infrared spectroscopic results proving the existence of carbonic acid in aqueous solution. A photoacid is used to optically trigger the ultrafast protonation of bicarbonate. Carbonic acid has only been detected as solid existing in ice matrices and in the gas phase, so far. Because carbonic acid is often postulated as intermediate between carbon dioxide and bicarbonate its characterisation is of substantial support in understanding fundamental acid-base chemistry of carbonates in aqueous solution as well as in biophysical situations. Analysing the time-dependent signals using a theoretical model to describe bimolecular reaction dynamics an on-contact proton transfer reaction rate is derived. This gives an insight into the acid-base chemistry of carbonic acid. Reaktionsmechanismen Elektrontransfer Femtochemie Schwingungsspektroskopie Ionenpaare Protontransfer Kohlensäure Dissoziationskonstante Isocyansäure reaction mechanisms electron transfer femtochemistry vibrational spectroscopy ion pairs proton transfer carbonic acid dissociation constant isocyanic acid 540 Chemie 30 Chemie ddc:540
106	Fully quantum dynamics of protonated water clusters / Dynamique totalement quantique d'agrégats d'eau protonés Mouhat, Félix 07 September 2018 (has links) De nos jours, il n'existe encore aucune théorie capable de proposer une description précise et quantitative du transfert de proton en solution. En effet, ce problème est complexe du fait de la grande diversité des interactions existant dans l'eau liquide, à savoir: des interactions non liantes de type Van der Waals, des liaisons faiblement covalentes et des liaisons hydrogènes remarquablement fortes. Ces dernières sont d'ailleurs à l'origine des nombreuses propriétés fascinantes de l'eau à l'échelle macroscopique. À cela s'ajoutent les effets quantiques nucléaires dus à la faible masse de l'hydrogène, qui modifient profondément la nature de la surface d'énergie potentielle décrivant le transfert de proton le long de sa coordonnée de réaction. Nous proposons dans cette thèse une approche tout quantique basée sur une description quasi exacte de la fonction d'onde du système par l'utilisation de méthodes stochastiques de type Monte Carlo Quantique. Cette technique, combinée avec le formalisme des équations de Langevin et des intégrales de chemin de Feynman, permet de simuler à un niveau de précision inédit, n'importe quel système chimique en phase gaz ou en solution. Nous appliquons cette méthodologie à des agrégats d'eau neutres ou protonés pour apporter de nouveaux éclaircissements sur les phénomènes microscopiques régissant la diffusion du proton hydraté dans de tels systèmes. Il est mis en évidence que la mobilité du proton est optimale pour des températures proches des conditions ambiantes, du fait de la compétition subtile entre les effets thermiques et quantiques nucléaires. / There is no theory up to now able to provide an accurate and quantitative description of the proton transfer (PT) yet. Indeed, the complexity of the problem stems from the large diversity of the existing interactions in liquid water, namely: non bonding Van der Waals interactions, weakly covalent bonds and remarkably strong H-bonds. The latter ones are at the origin of the numerous fascinating properties of water at the macroscopic scale. In addition to such interactions, the nuclear quantum effects arising from the hydrogen light mass deeply modify the potential energy surface, and must be taken into account. In this thesis, we propose a fully quantum approach based on an almost exact description of the electronic wave function by means of Quantum Monte Carlo (QMC) methods. Our novel technique combines QMC with a Langevin-based Molecular Dynamics and the Feynman's path integral formalism. This allows one to perform fully quantum simulations of systems in gas or condensed phase, at an unprecedented level of accuracy,. We apply our approach to neutral or charged protonated water clusters to shed light on the microscopic phenomena driving the proton diffusion in such systems. We discovered that the proton hopping is optimal for temperatures close to ambient conditions, due to the subtle competition between thermal and nuclear quantum effects. This is highly suggestive of the importance of quantum nuclear effects to make PT processes - relevant for life - most efficient at room temperature. Monte Carlo quantique Agrégats d'eau Transfert de proton Effets quantiques nucléaires Dynamique de Langevin Quantum Monte Carlo Langevin dynamics Path integral Protonated clusters Proton transfer Nuclear quantum effect 539.1
107	Proton pathways in energy conversion : K-pathway analogs in O2- and NO-reductases Gonska, Nathalie January 2017 (has links) Oxygen and nitric oxide reductases are enzymes found in aerobic and anaerobic respiration, respectively. Both enzyme groups belong to the superfamily of Heme-Copper Oxidases, which is further divided into several subgroups: oxygen-reducing enzymes into A-, B- and C-type and nitric oxide reductases into qNORs and cNORs. Oxygen reducing enzymes use the energy released from oxygen reduction to take up electrons and protons from different sides of the membrane. Additionally, protons are pumped. These processes produce a membrane potential, which is used by the ATP-synthase to produce ATP, the universal energy currency of the cell. Nitric oxide reductases are not known to conserve the energy from nitric oxide reduction, although the reaction is highly exergonic. Here, the detailed mechanism of a B-type oxidase is studied with special interest in an element involved in proton pumping (proton loading site, PLS). The study supports the hypothesis that the PLS is protonated in one and deprotonated in the consecutive step of the oxidative catalytic cycle, and that a proton is pumped during the final oxidation phase. It further strengthens the previous suggestion that the PLS is a cluster instead of a single residue or heme propionate. Additionally, it is proposed that the residue Asp372, which is in vicinity of the heme a3 propionates previously suggested as PLS, is part of this cluster. In another study, we show that the Glu15II at the entry of the proton pathway in the B-type oxidase is the only crucial residue for proton uptake, while Tyr248 is or is close to the internal proton donor responsible for coupling proton pumping to oxygen reduction. The thesis also includes studies on the mechanism and electrogenicity of qNOR. We show that there is a difference in the proton-uptake reaction between qNOR and the non-electrogenic homolog cNOR, hinting at a different reaction mechanism. Further, studies on a qNOR from a different host showed that qNOR is indeed electrogenic. This surprising result opens up new discussions on the evolution of oxygen and nitric oxide reductases, and about how energy conservation can be achieved. / <p>At the time of the doctoral defense, the following paper was unpublished and had a status as follows: Paper 4: Manuscript.</p> heme-copper oxidase cytochrome c oxidase membrane protein respiration electron transfer proton transfer redox reaction metalloprotein non-heme iron cytochrome ba3 flow-flash carbon monoxide liposome respiratory control ratio Biochemistry and Molecular Biology Biokemi och molekylärbiologi
108	Fructose-1,6-bisphosphate aldolase de classe II : aspects structural et dynamique dans le mécanisme réactionnel Jacques, Benoit 12 1900 (has links) La D-fructose-1,6-bisphosphate aldolase (FBPA) catalyse la réaction réversible d'aldolisation dans la voie métabolique du glucose, c'est-à-dire l'interconversion du dihydroxyacétone phosphate (DHAP) et du D-glyceraldéhyde 3-phosphate (G3P) en D-fructose 1,6-bisphosphate (FBP). Les aldolases sont regroupées en deux classes selon le mécanisme réactionnel : la classe I, dont fait partie l'enzyme humaine, catalyse la réaction en passant par la formation d'un intermédiaire covalent (base de Schiff), alors que les aldolases de classe II sont des métalloenzymes - un cation métallique divalent est requis pour son activité catalytique. L'aldolase de classe II, absente des mammifères, se retrouve notamment chez des agents pathogènes, par exemples Mycobacterium tuberculosis (tuberculose), Giardia lamblia (giardiase), Escherichia coli (infections diverses) et Helicobacter pylori (ulcère et cancer gastrique). Cette distribution en fait une cible potentielle dans la découverte de médicaments. La conception d'inhibiteurs spécifiques pour l'aldolase de classe II requiert une fine connaissance de sa catalyse enzymatique et de sa structure tridimensionnelle. Cette connaissance demeure incomplète, alors que l'ensemble des structures de complexes enzyme-inhibiteur ou enzyme-intermédiaire ne supporte pas une partie du mécanisme publié dans la littérature. Nous étudions le rôle catalytique de deux résidus situés chacun sur une boucle de surface mobile de l'aldolase de classe II de H. pylori et impliqués dans des étapes d'échange de proton. Les mutants simples H180Q et E142A ont été caractérisés cinétiquement et cristallisés pour la détermination de structure sur la base de la diffraction aux rayons X. Les structures cristallines des mutants complexés à des intermédiaires réactionnels ont été résolues. La déprotonation du groupe hydroxyle en C4 du FBP initie le clivage de la liaison en C3-C4 du cétohexose, première étape du mécanisme catalytique de rétro-aldolisation. Nos résultats identifient His180, sur la boucle beta6-alpha8, comme responsable de cet échange de proton. Ce résidu est un ligand de l'ion de zinc dans la structure native; le changement conformationnel observé suite à l'amarrage du phosphate en C1 de FBP libère His180 pour permettre le clivage. L'ion de zinc migre par la suite vers le site actif afin de faciliter la liaison du substrat et la stabilisation de l'intermédiaire énediolate. Nos résultats vont à l'encontre de l'hypothèse publiée précédemment sur le rôle catalytique de Asp82 dans cet échange de proton du groupe hydroxyle en C4, le rôle de ce dernier résidu se limitant plutôt au maintien de l'intégrité structurale du site actif. La libération du G3P nouvellement produit est suivie de la protonation stéréospécifique de l'intermédiaire énediolate générant le DHAP. La libération du DHAP complète ainsi le cycle catalytique. La protonation de l'intermédiaire énediolate est effectuée par l'intermédiaire du résidu Glu142, situé sur la boucle beta5-alpha7, ce qui concorde avec des études cinétiques publiées sur d'autres FBPA de classe II. Ces études ont attribué le même rôle à ce résidu conservé entre homologues. Nous avons par la suite établi un protocole de simulation de dynamique moléculaire pour évaluer le repliement de ladite boucle et ainsi comprendre le mode d'action du résidu Glu142. Des détails mécanistiques de l'étape de clivage s'ajoutent à nos connaissances actuelles; des questions subsistent quant à leur implication au reste de la catalyse. En attribuant un rôle crucial à la boucle beta6-alpha8 dans la catalyse et non limité à la liaison de substrats, cette boucle des aldolases de classe II peut devenir une cible dans le développement d'inhibiteurs. De plus, la migration de l'ion de zinc non dépendante de ligand suggère la possibilité de chélater et restreindre l'ion loin du site actif. / Fructose-1,6-bisphosphate aldolase catalyzes the reversible aldol reaction in glucose metabolism interconverting dihydroxyacetone phosphate (DHAP) and D-glyceraldehyde 3-phosphate (G3P) into D-fructose 1,6-bisphosphate (FBP). Aldolases are furthermore classified based on their reaction mechanism: class I aldolase (e. g. human aldolase) forms a covalent Schiff base intermediate with substrate, whereas class II aldolase utilizes a divalent metal cation in catalysis. Class II aldolase is commonly found in pathogenic organisms such as Mycobacterium tuberculosis (tuberculosis), Giardia lamblia (giardiasis), Escherichia coli (diverse infections) and Helicobacter pylori (ulcer and gastric cancer) but not in mammals. This distribution makes class II aldolase a potential target for drug discovery. Structure driven drug design depends on an explicit knowledge of the reaction mechanism of class II aldolase and its three-dimensional structure. Our current knowledge is lacking; existing aldolase crystal structures with reaction intermediates and with competitive inhibitors are not coherent with proposed mechanisms in literature. The present study focuses on the catalytic role of two residues, each located on a mobile loop of H. pylori class II aldolase and each implicated in a critical proton transfer step. Single mutants H180Q and E142A were characterized enzymatically and crystallized for X-ray structure determination. Crystal structures of reaction intermediates formed with substrate were determined. The catalytic mechanism requires proton abstraction at the FBP C4 hydroxyl group to initiate C3-C4 bond cleavage, first step of the retroaldol reaction. Our data supports His180 situated on the mobile loop beta6-alpha8, as the residue responsible for this proton transfer. Notably, His180 chelates the zinc ion in the native structure. The structural change induced due to C1 phosphate binding of FBP releases His180 to promote cleavage. Displacement of the catalytic zinc ion ensues, facilitating substrate binding and subsequent stabilization of the enediolate intermediate. Our results do not support the previous hypothesis of a catalytic role for Asp82 in C4 hydroxyl group proton abstraction; it rather plays an important role in maintaining structural integrity for active site binding. Displacement of the nascent aldehyde G3P and concomitant stereospecific protonation of the enediolate species generates the obligate triose phosphate, DHAP. Dissociation of DHAP from the active site completes the catalytic cycle. The residue responsible for initiating enediolate protonation was identified as residue Glu142, situated on mobile loop beta5-alpha7, and this is in agreement with previous kinetic studies of enediolate protonation in other class II aldolases, attributing the same role to this conserved residue. We devised a molecular dynamic simulation method to follow the catalytic loop folding event, further investigating details of the role of Glu142 in catalysis. We gained further knowledge of the cleavage event, although work remains to elucidate missing details of the catalysis and integrate our findings. By attributing a role in catalysis to loop beta6-alpha8 not limited to substrate binding, this loop of class II aldolases becomes a potential target in drug design. In addition, ligand independent zinc ion migration suggest it is possible to chelate the metal and restrain it far from the active site. Aldolisation Rétro-aldolisation Transfert de proton Métalloenzyme Cristallographie Diffraction aux rayons X Enzymologie Dynamique moléculaire Aldol reaction Retro-aldol reaction Proton transfer Metalloenzyme Crystallography X-ray diffraction Enzymologie Molecular dynamics
109	Dynamiques moléculaires utilisant un champ de force quantique semiempirique : développement et applications à des systèmes d'intérêt biologique / Molecular dynamics using a semiempirical quantum force field : development and applications to systems of biological interest Marion, Antoine 08 December 2014 (has links) Ce travail est destiné au développement de méthodes approchées de chimie quantique capables de traiter des systèmes biologiques de grande taille. En particulier, nous réalisons des simulations de dynamique moléculaire dans l'approximation de Born-Oppenheimer, permettant une description quantique de l'Hamiltonien électronique du système dans son entier : SEBOMD (SemiEmpirical Born-Oppenheimer Molecular Dynamics). Notre approche se base sur un Hamiltonien électronique semiempirique (SE). L'une des principales difficultés rencontrées lors d'une simulation SEBOMD de la phase condensée est représentée par le choix de la méthode SE. La plupart des méthodes courantes ne permettant pas une bonne description de certaines interactions fondamentales, nous avons développé une nouvelle approche. Cette méthode, dénommée PM3-PIF3, a été appliquée à l'étude par dynamique moléculaire de molécules organiques dans l'eau. Les résultats obtenus montrent que notre méthode est appropriée pour le traitement de molécules comportant des groupements hydrophobes et/ou hydrophiles en milieu aqueux. L'analyse des propriétés électroniques et vibrationnelles de ces molécules en présence du solvant valide également nos résultats vis-À-Vis d'autres études expérimentales et théoriques présentes dans la littérature. Finalement, nous nous sommes intéressés au processus d'autoprotolyse de l'eau en milieux confinés. Après avoir discuté du choix de l'Hamiltonien SE à utiliser pour cette étude, nous avons caractérisé le transfert de proton dans un agrégat d'eau. Nous avons établi une corrélation entre l'énergie libre associée à la première étape de ce transfert et certaines propriétés physiques collectives / The present work is devoted to the development of approximate quantum chemistry methods that are suitable to treat biological systems of large size. In particular, we run molecular dynamics under the Born-Oppenheimer approximation, allowing a quantum mechanical description of the electronic Hamiltonian of the full system: SEBOMD (SemiEmpirical Born-Oppenheimer Molecular Dynamics). Our method is based on a semiempirical (SE) electronic Hamiltonian. One of the key issues arising in a condensed phase SEBOMD simulation is represented by the choice of the SE method. Since most of the currently available approaches fail in describing some relevant intermolecular interactions, we developed a new correction of SE Hamiltonians. This method, which we named PM3-PIF3, was applied to study the molecular dynamics of organic molecules in water. The results that we obtained showed that our technique is suitable to treat molecules having hydrophobic and/or hydrophilic groups in an aqueous medium. The analysis of the electronic and vibrational properties of these molecules in the presence of the solvent validates our results with respect to experimental and theoretical studies in the literature. Finally, we investigated the water self-Dissociation process in confined environments. After discussing the choice of the SE Hamiltonian to be used for this purpose, we characterized the proton transfer in a water cluster. We established a correlation between the free energy of the first step of this process and some collective physical properties Dynamique moléculaire Born-Oppenheimer Méthodes quantiques semiempiriques Simulations en phase condensée Spectroscopie infrarouge Transfert de proton Agrégats d'eau Born-Oppenheimer molecular dynamics Quantum semiempirical methods Condensed phase simulations Infrared spectroscopy Proton transfer Water clusters 541.28
110	Spatiotemporal analysis of criteria air pollutants and volatile organic compounds from a moving vehicle Davidson, Jon 31 August 2021 (has links) This thesis describes the on-road analysis of criteria air pollutants (CAPs) and volatile organic compounds (VOCs) from a moving vehicle. CAPs and VOCs have numerous direct and indirect effects on the environment and public health and are generated from a variety of point and diffuse sources. The concentration of these pollutants can vary on the scale of metres and seconds due to variable emission rates of sources, meteorology, and the topography of an area. CAPs are conventionally measured on a spatial scale of tens of kilometres and one hour or longer time resolution, which limits the understanding of their impact and leaving many communities lacking information regarding their air quality. VOCs are not measured as frequently as CAPs, owing to the difficulty, challenges, and cost associated with sampling. The Mobile Mass Spectrometry Lab (MMSL) was developed to collect high geospatial (15 – 1,500 m) and temporal (1 – 10 s) resolution measurements of CAPs (O3, NOx, PM2.5), CO2, CH4, and VOCs. CAPs and greenhouse gases were monitored using standard analyzers, while VOCs were measured using a proton-transfer reaction time-of-flight mass spectrometer (PTR-MS). PTR-MS is a real-time, direct, in situ technique that can monitor VOCs in the ambient atmosphere without sample collection. The PTR-MS monitored up to mass-to-charge 330 with a sample integration time of 1 or 10 seconds and had detection limits into the low- to mid-ppt. PTR-MS is a soft ionization technique that is selective to all compounds with a proton affinity less than water, which excludes the atmospheric matrix and includes most VOCs. The measurements provided by the PTR-MS provided a rich dataset for which to develop workflow and processing methods alongside sampling strategies for the collection of high geospatial and temporal VOC data. The first on-road deployment of the MMSL was performed across the Regional District of Nanaimo and the Alberni-Clayoquot Regional District in British Columbia, Canada, from July iv 2018 – April 2019 to monitor the geospatial and temporal variation in the concentration of CAPs and VOCs. VOCs detected in the areas include hydrocarbons like toluene, C2-benzenes, and terpenes, organic acids like acetic acid, oxygenated compounds like acetone and acetaldehyde, and reduced sulfur compounds like methanethiol and dimethyl sulfide. While observed concentrations of VOCs were mostly below detection limits, concentration excursions upwards of 2,200 ppb for C2-benzenes (reported as ethylbenzene) for instance, were observed across the various communities and industries that comprise central Vancouver Island. VOCs like monoterpenes, were observed near the wood industries up to 229 ppb. Combustion related VOCs, like toluene and C2-benzenes, were often observed on major transportation corridors and was found to vary significantly between seasons, with winter measurements often exceeding those made in the summer. Reduced sulfur compounds, common components of nuisance odours, were measured around a few industries like waste management and wood industries. The second on-road deployment of the MMSL focused on the analysis of VOCs in the community around a wastewater treatment plant (WWTP) to identify the source of odours in the area. VOCs were also monitored in the odour control process of the WWTP to identify the VOCs being emitted, how much were emitted, and where potential deficiencies were in the process in a unique study. Median emission rates at the facility for methanethiol, dimethyl sulfide, and dimethyl disulfide were determined to be 100, 19, and 21 kg yr-1, respectively. VOC monitoring in the community encompassed the WWTP and the other major industries in the area, including agricultural land, a composting facility, and a marina. The highest measurements of odorous reduced sulfur compounds were observed around the WWTP, upwards of 36 ppb for methanethiol. Unsupervised multivariate analysis was performed to identify groups of VOCs present and their potential sources. Three groups were identified, one of which was related to reduced sulfur compounds. This group was observed around the WWTP, indicating that the WWTP was the likely source of malodours in the community. / Graduate PTRMS PTR-MS Mobile Mass Spectrometry Direct Mass Spectrometry Wastewater Treatment Geospatial Analysis Temporal Analysis Mobile Lab Methanethiol Dimethyl sulfide Air Quality Methods Development Mobile Measurements On-Road

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