Global ETD Search

1	The Coupled Water-Protein Dynamics within Hydration Layer surrounding Protein and Semiclassical Approximation for Optical Response Funtion Li, Tanping 26 September 2011 (has links) No description available. Biophysics solvation dynamics linear response theory optical response cunction
2	Ultrafast Protein Hydration Dynamics and Water-Protein Interactions Yang, Jin January 2016 (has links) No description available. Biochemistry Physics Biophysics
3	Études des réactions primaires en solutions par la radiolyse pulsée picoseconde / Picosecond Pulse Radiolysis Study of Primary Reactions in Solutions El Omar, Abdel Karim 04 November 2013 (has links) Après la découverte des rayonnements ionisants et leurs effets chimiques, il était important d’étudier et de comprendre les mécanismes de formations des radicaux libres et des produits moléculaires caractérisés par leurs courtes durées de vie. Ceci a encouragé les groupes de recherches à développer leurs outils pour qu’ils puissent réaliser ces études. De nos jours la radiolyse impulsionnelle se manifeste comme un outil fondamental permettant de sonder les effets chimiques ainsi que les mécanismes réactionnels dans le milieu étudié.Le laboratoire de Chimie Physique d’Orsay « LCP » est un laboratoire interdisciplinaire abritant la plateforme « ELYSE » qui est un centre de cinétiques rapides. Grâce au laser femtoseconde et à l’accélérateur d’électrons picoseconde, nous avons eu la possibilité, dans le domaine de la radiolyse, de remonter en temps, en étudiant les effets chimiques dans un milieu réactionnel, jusqu’à ~ 5 ps.Nous nous sommes intéressés par les réactions primaires induites par les rayonnements ionisants en solution et ELYSE représentait l’outil principal pour ces études. Les résultats obtenus concernent :- La détermination directe du rendement radiolytique du radical hydroxyle « HO• » en fonction du temps à l’échelle de la picoseconde ;- Etude de l’effet direct du rayonnement ionisant sur les solutions aqueuses concentrées ainsi que la vérification de la réaction de transfert d’électron ultrarapide entre le soluté et le trou positif « H2O•+ » issu lors de la radiolyse de l’eau ;- Etude à température ambiante de la réaction de transfert d’électron entre un électron solvaté (donneur d’électron) et un soluté organique (accepteur d’électron) en milieu visqueux ;- Etude à température ambiante de la solvatation de l’électron dans l’éthylène glycol et dans le propan-2-ol. / Following the discovery of ionizing radiations and their chemical effects, it was important to study and comprehend the formation mechanisms of short lived free radicals and molecular products. In order to perform such studies, researchers and research groups worked on developing tools allowing both formation and detection of those species at short time scales. Nowadays, pulse radiolysis imposed itself as a fundamental and efficient tool allowing scientists to probe chemical effects as well as reaction mechanisms in studied media.The laboratoire de Chimie Physique d’Orsay “LCP” is an interdisciplinary laboratory hosting the platform of fast kinetics known as “ELYSE”. Due to its femtosecond laser and its picosecond electron accelerator, we have the possibility to study chemical effects of ionizing radiations interaction with media at ultrashort times up to ~5 ps.Knowing that we are interested in primary reactions induced in aqueous media by ionizing radiations, ELYSE represents the essential tool in performing our studies. The obtained results concern:- First direct determination of hydroxyl radical “HO•” radiolytic yield as function of time at picosecond time scale ;- Direct effect of ionizing radiation in highly concentrated aqueous solutions as well as investigation of the ultrafast electron transfer reaction between solute molecules and positive holes “H2O•+” formed upon water radiolysis ;- Study at room temperature of electron transfer reaction between solvated electron (electron donor) and organic solutes (electron acceptors) en viscous medium ;- Study at room temperature of electron’s solvation dynamics in ethylene glycol and 2-propanol. Radiolyse pulsée picoseconde Effet direct Trou positif Solvatation Radical hydroxyle Picosecond pulse radiolysis Direct effect Positive hole Solvation dynamics Hydroxyl radical
4	Influência de parâmetros moleculares em funções de correlação temporal na dinâmica de solvatação mecânica / Influence of molecular parameters on time correlations functions of mechanical solvation dynamics Martins, Marcio Marques January 2004 (has links) No presente trabalho descrevemos nossos resultados relativos à investigação da dinâmica de solvatação mecânica por meio de simulações por dinâmica molecular, respeitando o regime da resposta linear, em sistemas-modelo de argônio líquido com um soluto monoatômico ou diatômico dissolvido. Estudamos sistematicamente a influência dos parâmetros moleculares dos solutos (tamanho, polarizabilidade) e da densidade frente a vários modelos de solvatação. Funções de Correlação Temporal da Energia de Solvatação foram calculadas com relação à correlações de n-corpos (n = 2; 3) distinguindo interações repulsivas e atrativas para ambos os sistemas líquidos. Também obtivemos segundas derivadas temporais dessas funções referindo-se à parcelas translacionais, rotacionais e roto-translacionais na solução do diatômico. Encontramos que funções de correlação temporal coletivas podem ser razoavelmente bem aproximadas por correlações binárias a densidades baixas e, a densidades altas, correlações ternárias tornam-se mais importantes produzindo um descorrelacionamento mais rápido das funções coletivas devido a efeitos de cancelamento parciais. As funções de correlação para interações repulsivas e atrativas exibem comportamentos dinâmicos independentes do modelo de solvatação devido a fatores de escalonamento linear que afetam apenas as amplitudes das dessas funções de correlação temporal. Em geral, os sistemas com grau de liberdade rotacional apresentam tempos de correlação mais curtos para a dinâmica coletiva e tempos de correlação mais longos para as funções binárias e ternárias. Finalmente, esse estudo mostra que os sistemas contendo o diatômico relaxam-se predominantemente por mecanismos translacionais binários em modelos de solvatação envolvendo alterações apenas na polarizabilidade do soluto, e por mecanismos rotacionais atrativos binários em modelos envolvendo alterações no comprimento de ligação. / In the present work, we describe our results concerning our molecular dynamics investigation of the mechanical solvation dynamics within the linear response regime in model systems composed by liquid argon with a monoatomic or diatomic solute. The effect of molecular parameters (size, polarizability) and density has been elucidated for various solvation models. Time Correlation Functions for the solvation energy were calculated and separated into n-body (n = 2; 3) contributions distinguishing repulsive and attractive interactions in both liquid systems. In addition, we computed second time derivatives of these functions in order to describe translational, rotational, and roto-translational portions in the solutions containing the diatomics. We found that collective time correlation functions are well described by binary correlations at low liquid densities and, at high densities, ternary correlations become more important producing faster decaying collective time correlation functions due to partial cancellation effects. The repulsive and attractive time correlation functions exhibit a dynamic behavior that is independent on the solvation model due to linear scaling factors that only affect the absolute amplitudes of these functions. In general, the systems involving a rotational degree of freedom furnish smaller correlation times for the collective solvation dynamics, but stronger correlated two-body and three-body terms. Finally, this study shows that the solvation dynamics for the solution containing the diatomics relaxes predominatly by binary translational mechanisms when solvation models involving changes only in the polarizability parameter are considered. Binary attractive rotational mechanism become important in models with changes in the bond length. Dinâmica molecular Solvatação Simulação computacional Molecular parameters Time correlation function Mechanical solvation dynamics Solvation energy Binary and ternary correlations Repulsive and attractive correlations Relaxation mechanisms Translation and rotation
5	Influência de parâmetros moleculares em funções de correlação temporal na dinâmica de solvatação mecânica / Influence of molecular parameters on time correlations functions of mechanical solvation dynamics Martins, Marcio Marques January 2004 (has links) No presente trabalho descrevemos nossos resultados relativos à investigação da dinâmica de solvatação mecânica por meio de simulações por dinâmica molecular, respeitando o regime da resposta linear, em sistemas-modelo de argônio líquido com um soluto monoatômico ou diatômico dissolvido. Estudamos sistematicamente a influência dos parâmetros moleculares dos solutos (tamanho, polarizabilidade) e da densidade frente a vários modelos de solvatação. Funções de Correlação Temporal da Energia de Solvatação foram calculadas com relação à correlações de n-corpos (n = 2; 3) distinguindo interações repulsivas e atrativas para ambos os sistemas líquidos. Também obtivemos segundas derivadas temporais dessas funções referindo-se à parcelas translacionais, rotacionais e roto-translacionais na solução do diatômico. Encontramos que funções de correlação temporal coletivas podem ser razoavelmente bem aproximadas por correlações binárias a densidades baixas e, a densidades altas, correlações ternárias tornam-se mais importantes produzindo um descorrelacionamento mais rápido das funções coletivas devido a efeitos de cancelamento parciais. As funções de correlação para interações repulsivas e atrativas exibem comportamentos dinâmicos independentes do modelo de solvatação devido a fatores de escalonamento linear que afetam apenas as amplitudes das dessas funções de correlação temporal. Em geral, os sistemas com grau de liberdade rotacional apresentam tempos de correlação mais curtos para a dinâmica coletiva e tempos de correlação mais longos para as funções binárias e ternárias. Finalmente, esse estudo mostra que os sistemas contendo o diatômico relaxam-se predominantemente por mecanismos translacionais binários em modelos de solvatação envolvendo alterações apenas na polarizabilidade do soluto, e por mecanismos rotacionais atrativos binários em modelos envolvendo alterações no comprimento de ligação. / In the present work, we describe our results concerning our molecular dynamics investigation of the mechanical solvation dynamics within the linear response regime in model systems composed by liquid argon with a monoatomic or diatomic solute. The effect of molecular parameters (size, polarizability) and density has been elucidated for various solvation models. Time Correlation Functions for the solvation energy were calculated and separated into n-body (n = 2; 3) contributions distinguishing repulsive and attractive interactions in both liquid systems. In addition, we computed second time derivatives of these functions in order to describe translational, rotational, and roto-translational portions in the solutions containing the diatomics. We found that collective time correlation functions are well described by binary correlations at low liquid densities and, at high densities, ternary correlations become more important producing faster decaying collective time correlation functions due to partial cancellation effects. The repulsive and attractive time correlation functions exhibit a dynamic behavior that is independent on the solvation model due to linear scaling factors that only affect the absolute amplitudes of these functions. In general, the systems involving a rotational degree of freedom furnish smaller correlation times for the collective solvation dynamics, but stronger correlated two-body and three-body terms. Finally, this study shows that the solvation dynamics for the solution containing the diatomics relaxes predominatly by binary translational mechanisms when solvation models involving changes only in the polarizability parameter are considered. Binary attractive rotational mechanism become important in models with changes in the bond length. Dinâmica molecular Solvatação Simulação computacional Molecular parameters Time correlation function Mechanical solvation dynamics Solvation energy Binary and ternary correlations Repulsive and attractive correlations Relaxation mechanisms Translation and rotation
6	Influência de parâmetros moleculares em funções de correlação temporal na dinâmica de solvatação mecânica / Influence of molecular parameters on time correlations functions of mechanical solvation dynamics Martins, Marcio Marques January 2004 (has links) No presente trabalho descrevemos nossos resultados relativos à investigação da dinâmica de solvatação mecânica por meio de simulações por dinâmica molecular, respeitando o regime da resposta linear, em sistemas-modelo de argônio líquido com um soluto monoatômico ou diatômico dissolvido. Estudamos sistematicamente a influência dos parâmetros moleculares dos solutos (tamanho, polarizabilidade) e da densidade frente a vários modelos de solvatação. Funções de Correlação Temporal da Energia de Solvatação foram calculadas com relação à correlações de n-corpos (n = 2; 3) distinguindo interações repulsivas e atrativas para ambos os sistemas líquidos. Também obtivemos segundas derivadas temporais dessas funções referindo-se à parcelas translacionais, rotacionais e roto-translacionais na solução do diatômico. Encontramos que funções de correlação temporal coletivas podem ser razoavelmente bem aproximadas por correlações binárias a densidades baixas e, a densidades altas, correlações ternárias tornam-se mais importantes produzindo um descorrelacionamento mais rápido das funções coletivas devido a efeitos de cancelamento parciais. As funções de correlação para interações repulsivas e atrativas exibem comportamentos dinâmicos independentes do modelo de solvatação devido a fatores de escalonamento linear que afetam apenas as amplitudes das dessas funções de correlação temporal. Em geral, os sistemas com grau de liberdade rotacional apresentam tempos de correlação mais curtos para a dinâmica coletiva e tempos de correlação mais longos para as funções binárias e ternárias. Finalmente, esse estudo mostra que os sistemas contendo o diatômico relaxam-se predominantemente por mecanismos translacionais binários em modelos de solvatação envolvendo alterações apenas na polarizabilidade do soluto, e por mecanismos rotacionais atrativos binários em modelos envolvendo alterações no comprimento de ligação. / In the present work, we describe our results concerning our molecular dynamics investigation of the mechanical solvation dynamics within the linear response regime in model systems composed by liquid argon with a monoatomic or diatomic solute. The effect of molecular parameters (size, polarizability) and density has been elucidated for various solvation models. Time Correlation Functions for the solvation energy were calculated and separated into n-body (n = 2; 3) contributions distinguishing repulsive and attractive interactions in both liquid systems. In addition, we computed second time derivatives of these functions in order to describe translational, rotational, and roto-translational portions in the solutions containing the diatomics. We found that collective time correlation functions are well described by binary correlations at low liquid densities and, at high densities, ternary correlations become more important producing faster decaying collective time correlation functions due to partial cancellation effects. The repulsive and attractive time correlation functions exhibit a dynamic behavior that is independent on the solvation model due to linear scaling factors that only affect the absolute amplitudes of these functions. In general, the systems involving a rotational degree of freedom furnish smaller correlation times for the collective solvation dynamics, but stronger correlated two-body and three-body terms. Finally, this study shows that the solvation dynamics for the solution containing the diatomics relaxes predominatly by binary translational mechanisms when solvation models involving changes only in the polarizability parameter are considered. Binary attractive rotational mechanism become important in models with changes in the bond length. Dinâmica molecular Solvatação Simulação computacional Molecular parameters Time correlation function Mechanical solvation dynamics Solvation energy Binary and ternary correlations Repulsive and attractive correlations Relaxation mechanisms Translation and rotation
7	Ultrafast Hydration Dynamics Probed by Tryptophan at Protein Surface and Protein-DNA Interface Qin, Yangzhong 14 May 2015 (has links) No description available. Biophysics Physics Biochemistry
8	Ultrafast studies of reactive intermediates Wang, Jin 10 December 2007 (has links) No description available. Carbene Nitrene Wolff Rearrangement Carbene Interconversion Carbene singlet excited states Carbene solvation dynamics Intersystem Crossing Diazirine Diazo Nitrenium Carbenium Solvent Effects Ultrafas
9	Local THz spectroscopy in the condensed phase Hezaveh, Mohsen Sajadi 30 March 2012 (has links) In dieser Arbeit wird die Solvatationsdynamik einer solvatochromen molekularen Sonde diskutiert, und zwar als Methode für den Erhalt von lokalen IR-THz-Spektren von komplexen Systemen. Durch Femtosekundenanregung wird die Ladungsverteilung der Sonde verändert, und als Folge davon wird ein elektrisches Feld induziert. Zu diesem Zeitpunkt wirkt die im Lösungsmittel gelöste Sonde als Lichtquelle mit THz-Frequenzen. Da durch die Anregung das Gleichgewicht des Systems gestört wird, reorganisieren sich die Lösungsmittelmoleküle, sodass ein neues Gleichgewicht im angeregten Zustand entsteht. Die Bewegung der Lösungsmittelmoleküle ist (in gemittelter Form) als Stokes-Verschiebung des Fluoreszenz-Bandes beobachtbar. Durch eine geeignete Transformation der zeitaufgelösten Stokes-Verschiebung erhält man ein lokales IR-THz-Spektrum. Das Sondenmolekül wirkt daher auch als ein Detektor. Der Vorteil eines solchen "molekularen Spektrometers" ist sein mikroskopischer Aufenthaltsort, der u.a. sehr wichtig wird, wenn Messungen in Wasser durchgeführt werden: In diesem Fall macht eine intensive Absorption durch das Lösungsmittel das Eindringen von externen THz Strahlen tief in die Probe unmöglich. / Solvation dynamics of a solvatochromic molecular probe is discussed as a method to yield local IR-THz spectra of complex systems. After femtosecond excitation, the charge distribution of the probe is altered and, as a consequence, an electric field is generated. At this stage the solute acts as a light source with THz frequencies. Since by excitation the equilibrium of the system is perturbed, solvent molecules reorganize such that a new equilibrium is created in the excited state. This motion of solvent molecules can be seen (in an averaged form) by recording the Stokes shift of the fluorescence band. By an appropriate transformation of the time-resolved Stokes shift, a local IR-THz spectrum is obtained. The probe molecule therefore also acts as a detector. The advantage of such a “molecular spectrometer” is its locality, which becomes important when measurements are made in water. In this case, intense absorption by the solvent makes impossible the penetration of external THz beams deep into the sample. Solvatationsdynamik Breitband Fluoreszenz Aufkonvertierung lokale THz Spektroskopie Supramolekulare Oszillationen Solvation dynamics Broadband fluorescence upconversion local THz spectroscopy Supramolecular oscillations. 530 Physik 29 Physik, Astronomie UH 5710 UM 3200 ddc:530
10	Structure And Dynamics Of Constrained Water : Microscopic Study Of Macromolecular Hydration Using Computer Simulations Pal, Subrata 02 1900 (has links) The thesis, which contains nine chapters, reports extensive large scale atomistic molecular dynamics (MD) simulation studies of water structure and dynamics at the surface of an anionic micelle, hydration layer of two proteins, and in the grooves of a 38-base pairs long DNA. Understanding the structure and dynamics of water molecules at the surfaces of self-organized assemblies and complex biological macromolecules has become a subject of intense research in recent times. Chapter 1 contains a brief overview of the biomolecular hydration dynamics. Relevant experimental, computational, and theoretical studies of biomolecular hydration and the time scales associated with the water dynamics are discussed. In Chapters 2 and 3, the structure, environment, energetics, and dynamics of constrained water molecules in the aqueous anionic micelle of cesium perfluorooctanoate (CsPFO) have been studied using large scale atomistic molecular dynamics simulations. Based on the number of hydrogen bond (HB) that interfacial water molecule makes with the polar head group (PHG) oxygen of the micelle, we find the existence of three kinds of water at the interface. We introduce a nomenclature to identify the species as IBW2 (form two HBs with two different PHG), IBW1 (form one HB with PHG), and IFW (no HB with PHG). Despite of possessing two strong w-PHG bonds, the concentration of the IBW2 species is rather low due to entropic effect. The ion solvation dynamics study at the interface shows the presence of a slow component, with a relaxation time 1-2 order of magnitude slower than that in the corresponding bulk solvent in agreement with the experimental results. Both the translational and orientational dynamics of the water molecules near the micellar surface is found to be much slower than those in the bulk. The HB between the PHG of the micelle and the water molecule has almost 13 times longer life time than that in the bulk between two tagged water molecules. In Chapter 4, we present results of extensive atomistic MD simulation studies of the structure and dynamics of aqueous protein solution of the toxic domain of Enterotoxin (1ETN) and the chicken villin headpiece sub-domain containing 36 amino acid residues (HP-36). Reduced water structure and the faster water dynamics around the active site of these proteins have been observed which may have biological significance. Chapter 5 presents an extensive atomistic molecular dynamics simulations study of water dynamics in the hydration layer of a 38 base long hydrated DNA duplex. The computed rotational time correlation function (TCF) of the minor groove water dipoles is found to be markedly non-exponential with a slow component at long time. The constrained water molecule is also found to exhibit anisotropic diffusion in both the major and minor grooves. At short-to-intermediate times, translational motion of water molecules in minor groove is sub-diffusive. Chapter 6 presents the study of water entropy in both the grooves DNA. The average values of the entropy of water at 300K in both the grooves of DNA are found to be significantly lower than that in bulk water. We propose that the configurational entropy of water in the grooves can be used as a measure of the mobility (or micro viscosity) of water molecules in a given domain. In Chapter 7, we study the specific DNA base-water hydrogen bond lifetime (HBLT) dynamics at the major and the minor grooves of a hydrated duplex. The base-water HBLT correlation functions are in general multi-exponential and the average lifetime depends significantly on the specificity of the DNA sequence. The average HBLT is longer in the minor groove than that in the major groove by almost a factor of 2. Chapter 8 presents the solvation dynamics of constituent bases of aqueous DNA duplex. The solvation TCFs of the four individual bases display highly non-exponential decay with time. An interesting negative cross-correlation between water and counterions is observed which makes an important contribution to relaxation at intermediate to longer times. In the concluding note, Chapter 9 presents a brief summary of the outcome of the thesis and suggests several relevant problems that may prove w orthwhile to be addressed in future Water Chemistry - Computer Simulation Macromolecular Hydration Anionic Micelle Biomolecular Hydration Dynamics Water Dynamics Protein - Water Dynamics DNA Hydration Dynamics 1ETN Protein Aqueous Micelle Aqueous Miceller Surface Aqueous Micellar Solution Solvation Dynamics Inorganic Chemistry

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