Studies on binuclear Schiff-base compartmental ligand complexes

Black, Daniel

January 1997

No description available.

546

Protonated macrocycles

Reactions of alkenes with nitrogen containing reagents

Hewlins, Stuart A.

January 1995

No description available.

547

Protonated cyclopropane; Azidyl radical

The Electronic Structure and Spectroscopy of Diarylidene-Cycloalkanones and Their Protonated Cations

Ucak-Astarlioglu, Mine Gunes

06 May 2003

A series of 2,5-diarylidene-cyclopentanones (ndbcp), their protonated cations (ndbcp-H+), and a substituted compound, 2,5-bis-[3-(4-dimethylamino-phenyl)-allylidene-cyclopentanone (2dbma) have been synthesized. Their electronic absorption and fluorescence spectra have been measured. The absorption spectra have been assigned with the aid of INDO/S calculations. Molecular structures used for the INDO/S calculations were computed with the PM3 Hamiltonian. Polarized excitation spectra have been measured for 2dbcp and 3dbcp at 77 K in ethanol/methanol glass and used as an aid for the assignments of electronic transitions. Absorption and fluorescence spectra have been measured in solvents of varying polarity for all compounds synthesized. The influence of hydrogen bonding on the excitation spectra of compounds has been investigated. Solvent induced shifts in the absorption and fluorescence spectra of 3dbcp and 2dbma in combination with the PM3 calculated ground state dipole moment have been used to determine the excited state dipole moment of these compounds. Fluorescence quantum yields have been obtained to analyze the changes in the nonradiative rate of decay from S1. The protonated cations have been prepared in acids of different strength. The influence of acid strength on the excitation and emission spectra has been analyzed by gradually diluting acid solution. Evidence for excited state proton transfer in weak acids has been obtained for 2dbcp and 3dbcp. Brief photochemical studies of 1dbcp and 1dbcp-H+ have been carried out and analyzed by HPLC.

polyene ketones

diarylidene-cycloalkanones

spectroscopy

electronic structure

protonated cations

photochemistry

electronic states

Ketones

Photochemistry

Computational Investigation of the Photoisomerization of Novel N-Alkylated Indanylidene Pyrroline Biomimetic Switches

Ryazantsev, Mikhail N.

19 August 2010

No description available.

Chemistry

rhodopsin

photochemical switches

molecular motors

CASSCF

CASPT2

Conical Intersection

QM/MM

Theoretical Treatments of the Effects of Low Frequency Vibrations on OH Stretches in Molecules and Ion-Water Complexes that Undergo Large Amplitude Motions

Dzugan, Laura C.

21 September 2017

No description available.

Chemistry

proton transfer

protonated water clusters

ion-water complexes

low frequency motions

OH stretches

H-bonding

Tuning ultrafast chemical reaction dynamics in photoactive proteins

Bassolino, Giovanni

January 2015

This dissertation investigates the origins of tunable and efficient photochemistry in three different photoactive proteins, bacteriorhodopsin (BR), rhodopsin (RHO) and green fluorescent protein (GFP). In all cases, significant differences exist between the photoreactivity of model chromophores in solution and in the protein environment, in terms of excited state lifetime and efficiency of the primary photochemical process (opsin proteins) or the type of reaction (excited state proton transfer versus C=C double bond photoisomerisation for GFP). The work presented here investigates for each case to what extent the protein environment is necessary to alter the photochemistry of model chromophores in solution. For GFP and BR steric and electrostatic interactions between the protein pocket and the chromophore are shown to be likely responsible for shaping the excited state surface along which the photoreactions take place. For RHO it is suggested, contrary to current belief, that selection of a reactive ground state conformer might be the main effect generating the observed differences between solution and protein environment. The solution photochemistry of structurally modified retinal protonated Schiff bases, taken as model chromophores for the opsin proteins, is studied with continuous wave irradiation experiments and ultrafast transient spectroscopies. Surprisingly large differences are observed for the isomerisation reaction depending on the starting configuration (trans or cis) of the photoactive double bond. The current model for BR based on the tuning of the excited state barrier encountered along the isomerisation coordinate is expanded to include the changes in selectivity, speed and efficiency observed for a series of all-trans derivatives. For 11-cis, the photoisomerisation in solution is proposed to take place along a barrierless isomerisation coordinate, in contrast with the models currently available in literature. It is suggested that the protein might be discriminating between ground state conformers rather than significantly changing the topography of the reaction coordinate. For GFP, excited state Raman spectra are recorded for the wild-type protein, two mutants and a model chromophore in solution. It is suggested that the high frequency vibrational modes observed in the excited state spectra of the proteins but not of the model chromophore in DMSO are a sign of a tighter chromophore environment that inhibits the photoisomerisation reaction occurring in solution.

541

A full-dimensional quantum Monte Carlo study of H5O2+

Cho, Hyung Min

17 June 2004

No description available.

Chemistry, Physical

H5O2+

Protonated Water Dimer

Qunatum Monte Carlo

Correlation Function Quantum Monte Carlo

CFQMC

Excited States

Mechanisms and kinetics of alkenes isomerization and cracking in chabazite zeolite quantified by constrained ab initio molecular dynamics / Mécanismes et cinétique de l’isomérisation et du craquage d’alcènes dans la zéolithe chabazite quantifiés par dynamique moléculaire ab initio contrainte

Rey, Jérôme

20 September 2019

Les catalyseurs d’hydrocraquage et d’hydroisomérization sont bifonctionnels, avec une fonction hydro-déshydrogénante et une fonction acide, une zéolithe protonée, pour isomériser et craquer les alcènes. Par dynamique moléculaire ab initio avancée, et avec prise en compte explicite des effets thermiques (300 – 500 K), nous avons étudié les mécanismes d’isomérisation et de craquage d’alcènes C7 dans la zéolithe chabazite dans le but d’obtenir des constantes de vitesse fiables et d’interpréter la distribution des produits.Par la méthode blue moon, nous avons établi les premiers profils d’énergie libre d’isomérisations d’alcènes C7, avec des carbocations intermédiaires (et des états de transition cyclopropanes protonés, PCP), reliant des isomères di- à tri- et mono- à di-branchés (Sections III et IV). Nos simulations démontrent que les effets dynamiques et l’échantillonnage correct des rotamères jouent un rôle crucial sur la stabilité des intermédiaires et des états de transition. Ces effets ne pouvaient pas être décrits par les précédentes études de DFT statiques. Les barrières bien plus basses pour l’isomérisation de type A sont ainsi retrouvées, et expliquées par un état de transition mou, alors que l’état de transition de l’isomérisation de type B est contraint, à cause de la formation d’un edge PCP. L’étude des réactions de craquage avec les mêmes méthodes (Section V) éclaircit le rôle des cations secondaires. Pour la première fois, nous identifions les états de transitions des β-scissions. Nous déduisons de cette analyse des constantes de vitesse ab initio qui pourront être utilisées dans un modèle cinétique pour prédire l’activité et la sélectivité du catalyseur. / Hydrocracking and hydroisomerization catalysts are bifunctional, with a hydro-dehydrogenation function and an acidic function, typically an acid zeolite, to isomerize and crack alkenes. With advanced ab initio molecular dynamics approach, and explicit simulation of the effects of temperature (300 – 500 K), we investigate the mechanisms of isomerization and cracking reactions of C7 alkenes within the chabazite zeolite in order to provide reliable rate constants and explain the observed products distribution. By blue moon sampling, we established for the first time, the free energy profiles for the isomerization of C7 alkenes in zeolites, with carbenium ions as intermediates (and protonated cyclopropane (PCP) as transition states), connecting di- to tri-branched, and mono- to di-branched alkene isomers (Sections III and IV). We demonstrate that the dynamic effects with the correct sampling of rotational conformers play an important role to quantify the stability of the key intermediates and transition states. These effects could not be captured by previous static DFT simulations. The much lower barriers for type A isomerization mechanisms are thus recovered, and assigned to a loose transition state, while the transition state of type B isomerization is tighter, due to the formation of an edge PCP. The study of cracking reactions (Section V) with the same methods, unravel the role of secondary cations. For the first time, we identify the structures of transition states involved in the β-scission mechanisms. From this analysis, we deduce the ab initio- rate constants that could be used in future kinetic modeling to predict activity and selectivity of the catalyst.

Zéolithe

DFT

Dynamique moléculaire ab initio

Cyclopropane protoné

Cinétique

Hydroisomérisation

Craquage

Zeolite

DFT

Ab initio molecular dynamics

Protonated cyclopropane

Kinetics

Hydroisomerization

Cracking

Toward understanding speed, efficiency and selectivity in retinal photochemistry

Sovdat, Tina

January 2014

This Thesis describes the synthesis, structural, photochemical and photophysical studies of modified retinal protonated Schiff bases in solution. Ultrafast laser spectroscopy, NMR and circular dichroism studies were employed to investigate speed, yield and selectivity of photoisomerisation in these chromophores. <b>Chapter 1</b> introduces relevant biological, photophysical and photochemical aspects of retinal protonated Schiff base photoisomerisation. It includes an overview of synthetic approaches to modified retinal synthesis pertinent to this this work. <b>Chapter 2</b> discuses the investigation of the hypothesis that twisting of the chromophore’s isomerising double bond is responsible for ultrafast photoisomerisation in the protein environment. In these studies it was discovered that addition of a methyl group to the retinal backbone in solution results in protein-like photophysics. <b>Chapter 3</b> presents photopysical and photochemical studies of modified all-trans retinal protonated Schiff bases that culminate in a qualitative model for the influence of electronic factors on photochemical and photophysical behaviour of these chromophores in solution. <b>Chapter 4</b> describes structural and photophysical investigations of 11-cis retinal protonated Schiff bases. NMR studies indicate conformational flexibility of the chromophores. The first synthetic solution-based chromophore to reach rhodopsins’s speed of photoisomerisation is described. <b>Chapter 5</b> presents an attempt to gain conformational information on retinal protonated Schiff bases using circular dichroism spectroscopy. Transfer of stereochemical information from the covalently attached stereogenic centre to the retinal backbone is demonstrated.

541

Etude par dynamique moléculaire des propriétés structurales, dynamiques et thermodynamiques d'agrégats moléculaires / Molecular dynamics study of structural, dynamical and thermodynamical properties of molecular clusters

Korchagina, Kseniia

28 October 2016

Les agrégats de molécules d'eau constituent une classe d'espèces chimiques importante du fait de leur rôle central dans de nombreux processus physico-chimiques et biologiques terrestres, en particulier, les processus atmosphériques. Leurs propriétés physiques et chimiques sont particulièrement sensibles aux effets de taille et aux effets de température, ce qui les rend particulièrement difficile à caractériser expérimentalement. Ainsi, mes travaux de thèse ont porté sur l'étude théorique des propriétés structurales, dynamiques et thermodynamiques ainsi que sur la réactivité de divers agrégats de molécules d'eau avec pour objectif de mettre en place des outils de modélisation adaptés, permettant une description plus fine de ces systèmes. Pour cela, nous avons utilisé des approches de dynamique moléculaire de type "parallel-tempering" qui ont été couplées avec des calculs d'énergie et de gradient réalisés par la méthode Self-Consistent-Charge Density-Functional based Tight-Binding (SCC-DFTB). Trois grands volets ont été abordés au cours de ces travaux. Dans la première partie, l'analyse détaillée des structures des agrégats d'eau (H2O)nSO24- et (H2O)nH2SO4 avec n=1-20 est présentée. Nous avons mis en évidence l'influence de la nature de l'impureté soufrée sur le réseau de liaisons hydrogène de ces agrégats. La deuxième partie de cette thèse porte sur l'étude de la transition de phase "solide-liquide" dans divers agrégats de molécules d'eau. En plus des agrégats soufrés évoqués ci-dessus, nous avons également étudié des agrégats d'eau protonés contenant de 19 à 23 molécules d'eau. Pour mieux comprendre le mécanisme de transition de phase, nous avons considéré divers changements structuraux associés à la transition tels que l'évolution des distributions d'angles intermoléculaires et l'évolution du nombre de cycles de molécules dans l'agrégat. Nous avons également caractérisé la transition de phase au travers d'indicateurs dynamiques tels que la fréquence de transfert du proton en excès. La dernière partie de cette thèse est consacrée à l'étude de l'influence de petits agrégats d'eau (allant de 1 à 10 molécules d'eau) sur la réaction de recombinaison entre l'atome H et la molécule CO. Cette réaction est la première étape de formation des molécules organiques oxygénées simples dans le milieu interstellaire. Elle présente donc un intérêt particulier. Grâce à l'analyse de dynamiques collisionnelles entre H et CO ainsi qu'au calcul de sections efficaces de réaction, nous avons montré que la présence des molécules d'eau joue un rôle important dans le processus de formation du radical HCO. / Water clusters constitute an important class of chemical species due to their central role in many physico-chemical and biological processes, in particular, atmospheric processes. Their physical and chemical properties are particularly sensitive to size and finite-temperature effects, which makes them particularly difficult to characterize experimentally. This thesis focused on the theoretical investigation of the structural, dynamical and thermodynamical properties as well as on the reactivity of various water clusters with the aim to implement appropriate modeling tools to enable a more detailed description of these systems. To do so, we used the paralleltempering molecular dynamics approach that was coupled with calculations of energies and gradients carried out by the Self-Consistent-Charge Density-Functional based Tight-Binding (SCC-DFTB) method.Three main areas were addressed during the work. In the first part, a detailed analysis of the structure of water clusters (H2O)nSO24- and (H2O)nH2SO4 with n=1-20 is performed. This study highlights the influence of the nature of the sulfur impurity on the hydrogen bond network of these species.The second part of this thesis focuses on the study of the "solid-liquid" phase transition in various water clusters. In addition to the sulfur-containing water clusters mentioned above, we also investigated protonated water clusters containing from 19 to 23 water molecules. To better understand the phase transition mechanism, we considered various structural changes associated with the transition, such as the evolution of the distributions of intermolecular angles and the evolution of the number of molecular rings in the cluster. We also characterized the phase transition through dynamical indicators such as the crossover frequency of the excess proton. The last part of this thesis is devoted to the study of the influence of small water clusters (from 1 to 10 water molecules) on the recombination reaction between the H atom and the CO molecule. This reaction is the first step in the formation of simple oxygenated organic molecules in the interstellar medium. It is therefore of particular interest. Due to the analysis of collisional dynamics between H and CO and the calculation of effective reaction cross sections we showed that the presence of water molecules plays an important role in the HCO radical formation.

Agrégats moléculaires

Dynamique moléculaire

Chimie quantique

SCC-DFTB

Effets de température

Agrégats protonés

Molecular aggregates

Molecular dynamics

Quantum chemistry

SCC-DFTB

Finite-temperature effects

Protonated aggregates