Assessment of density functional methods for computing structures and energies of organic and bioorganic molecules

Cao, Jie

January 2011

The work in this thesis mainly focuses on the assessment of density functional methods for computing structures and energies of organic and bioorganic molecules. Previous studies found dramatic conformational and stability changes from B3LYP to MP2 geometry optimization for some Tyr-Gly conformers. Possible reasons could be large intramolecular basis set superposition errors (BSSEs) in the MP2 calculations and the lack of dispersion in the B3LYP calculations. The fragmentation method and three kinds of rotation methods were used to investigate intramolecular BSSE. It is concluded that the rotation method cannot be used to correct intramolecular BSSE along a rotation profile. Another methodology is to employ modern density functionals. We focused on M06-L with the Tyr-Gly conformer ‘book6’. Potential energy profiles were determined by computing the energy for geometries optimized at various fixed values of a distance that controls the degree of foldedness of the structure. M06-L manifested itself as a very promising method to investigate the potential energy surface of small peptides containing aromatic residues. To predict Tyr-Gly structures, 108 potential conformers were created with a Fortran program. The geometry optimizations were done using M06-L/6-31G(d) and M05-2X/6-31+G(d). Two schemes were employed and the most stable conformers were compared to the 20 stable conformers found by B3LYP. Both schemes found 10 conformers similar to one of the B3LYP stable conformers, as well as several newly found conformers. The study of a missing B3LYP stable conformer showed that the possible reason of missing conformers may be the lack in dispersion in B3LYP theory. To study the hydration effect, we studied the conformations of neutral and zwitterionic 3-fluoro-γ-aminobutyric acid (3F-GABA) in solution using different solvation models, mainly the explicit water molecule models. Zwitterionic forms of 3F-GABA are preferred in solution. M06-2X performs better in calculating transition energy profiles than MP2.

547.13

Compréhension des mécanismes d'incompatibilité chimique du nitrate d'ammonium par modélisation moléculaire / Understanding the mechanisms of chemical incompatibility ammonium nitrate by molecular modeling

Cagnina, Stefania

27 October 2014

De nombreuses substances chimiques sont susceptibles de mener à des phénomènes d'incompatibilité, lors de leur mise en contact avec d'autres produits ou matériaux. Pour maîtriser ces risques, une identification rapide et précise de ces incompatibilités est nécessaire. Elle est réalisée, jusqu’à présent, par des outils expérimentaux qui malgré leur incontestable importance, ne fournissent que des informations limitées. Pour les compléter et améliorer la compréhension des processus d'incompatibilité, ce travail de thèse, vise à étudier la réactivité du nitrate d'ammonium, produit très utilisé dans l'industrie, connu pour sa longue liste d'incompatibilités et impliqué dans des nombreux accidents majeurs (Toulouse 2001), à l'aide de la modélisation moléculaire. Une étude théorique approfondie, basée sur des calculs DFT, destinée à identifier les chemins réactionnels, les produits formés ainsi que la chaleur dégagée par les réactions a été menée.Après avoir caractérisé le mécanisme radicalaire de décomposition du nitrate d’ammonium pur en phase gaz, une étude détaillée de la réactivité du mélange du nitrate d’ammonium et du dichloroisocyanurate de sodium (DCCNa), a été réalisée. Un chemin réactionnel a été caractérisé, il s'agit de la réaction directe entre le nitrate d'ammonium et le DCCNa, en présence d'une molécule d'eau. Ensuite, ces méthodes théoriques ont été appliquées à d'autres systèmes d'incompatibilités chimiques avec le nitrate d'ammonium (NaNO2, substances chlorées) en focalisant sur les étapes limitantes des mécanismes afin de tester leur pertinence et potentiel en tant qu'outil de prédiction a priori du phénomène d'incompatibilité. Ce travail, pionnier dans l'étude microscopique des incompatibilités chimiques du nitrate d'ammonium, a permis de clarifier les mécanismes réactionnels lors de la décomposition du produit pur et en contact avec des contaminants. / Numerous chemical reactants tend to lead to undesired phenomena of incompatibility. In order to prevent the happening of those phenomena, a rapid and accurate identification of the incompatibilities is needed. Until now, experimental studies, which provide insightful, but limited information, were the only possible approach used for the study of incompatibilities. In this work a molecular modeling approach was used in order to complete and improve experimental results of incompatibility processes for the reactivity of ammonium nitrate. Ammonium nitrate is a widely used compound in the chemical industry, known for its long list of incompatibilities and often involved in major accidents (Toulouse, 2001).This theoretical work, based on Density Functional Theory (DFT) calculations, is intended to provide insights into the possible reaction pathways, enthalpies and products formed by incompatibility reaction between ammonium nitrate and other compounds. In this thesis the mechanism of the decomposition of pure ammonium nitrate in the gas phase was firstly characterized and then the reactivity of the mixture of ammonium nitrate – sodium dichloroisocyanurate (DCCNa) was considered. The results obtained suggest the existence of a reaction path, involving a direct reaction between the ammonium nitrate and DCCNa in the presence of a molecule of water.Furthermore, the theoretical approach was employed focusing on the study of the limiting steps of other chemical incompatibilities for ammonium nitrate systems (NaNO2, chlorinated substances). Those results were employed to understand the potentiality of the theoretical approach as a priori predicting tool for the incompatibility processes.In summary this work, pioneer in the microscopic study of chemical incompatibilities of ammonium nitrate, has clarified the reaction mechanisms involved in the decomposition of pure compounds, as well as in contact with other contaminants.

Incompatibilités chimiques

DFT

Nitrate d'ammonium

Risque industriel

Modélisation moléculaire

M06-2x

Chemical incompatibility

Ammonium nitrate

541.2

Investigating the structure and dynamics of DNA with fluorescence and computational techniques

Smith, Darren Andrew

January 2015

Nucleic acids, such as DNA, play an essential role in all known forms of life; however, despite their fundamental importance, there is still a significant lack of understanding surrounding their functional behaviour. This thesis explores the structure and dynamics of DNA by employing methods based on fluorescence and through the use of computational calculations. Time-resolved fluorescence experiments have been performed on dinucleotides containing 2-aminopurine (2AP) in various alcohol-water mixtures. 2AP, a fluorescent analogue of the nucleobase adenine, has been used extensively to investigate nucleic acids because of its ability to be incorporated into their structures with minimal perturbation and its high sensitivity to its local environment. Direct solvent effects on 2AP were established through measurements on the free fluorophore. Analysis of the complex fluorescence decays associated with the dinucleotides was challenging but has provided insight into their conformational dynamics. Solvent polarity was found to play a significant role in determining both photophysical and conformational properties in these systems. The complicated fluorescence decay of 2AP in nucleic acids highlights the need for accurate and unbiased analysis methods. Various time-resolved fluorescence analysis methods, including iterative reconvolution and the exponential series method, have been investigated with real and simulated data to obtain an overview of their benefits and limitations. The main outcome of the evaluation is that no single method is preferred in all situations and there is likely to be value in using a combination when there is ambiguity in the interpretation of the results. Regardless of the analysis technique used, the parameterised description of the observed fluorescence decay is meaningless if the underlying physical model is unrealistic. The advance of computational methods has provided a new means to rigorously test the viability of proposed models. Calculations have been performed at the M06-2X/6-31+G(d) level of theory to investigate the stability of 2AP-containing dinucleotides in conformations similar to those observed in the double-helical structure of DNA. The results help to explain the similarity of the time-resolved fluorescence behaviour of 2AP in dinucleotide and DNA systems but also bring to light subtle differences that could perhaps account for experimental discrepancies. The recent emergence of advanced optical microscopy techniques has offered the prospect of being able to directly visualise nucleic acid structure at the nanoscale but, unfortunately, limitations of existing labelling methods have hindered delivery of this potential. To address this issue, a novel strategy has been used to introduce reversible fluorescence photoswitching into DNA at high label density. Photophysical studies have implicated aggregation and energy-transfer as possible quenching mechanisms in this system, which could be detrimental to its future application. The reliability of fluorescence photoswitching was investigated at ensemble and single-molecule level and by performing optical lock-in detection imaging. These developments lay the foundations for improved and sequence-specific super-resolution microscopy of DNA, which could offer new insights into the 3D nanoscale structure of this remarkable biopolymer. In summary, the work presented in this thesis outlines important observations and developments that have been made in the study of the structure and dynamics of nucleic acids.

572

An Investigation into the Use of Density Functional Theory (DFT) Calculations for Predicting Vibrational Transitions for Perfluroinated Sulfonic Acid (PFSA) Ionomer Membranes

Schultz, Spencer Albert

05 February 2019

Perfluorinated sulfonic acid (PFSA) ionomer membranes demonstrate great potential for use in proton exchange membrane fuel cells (PEMFCs) due to their favorable electronic properties and excellent efficiency. However, the assignment of key vibrational transitions such as the symmetric sulfonate and ether stretches is not yet fully understood depriving researchers of a quick and simple technique for analyzing morphological changes. The symmetric sulfonate stretch could be used to track changes in the ionic clusters formed within the membrane while the ether stretch will provide insight into the largely semi-crystalline PTFE phase. Alterations in either regime will affect both ion transport and mechanical properties and produce a major shift in device performance. This study focused on predicting the vibrational transitions for Aquivion, 3M PFSA, and Nafion using density functional theory (DFT) with the bulk being performed using the same functional and basis set combination, B3LPY/6-31+G*. For all three ionomers, the predicted vibrational transitions were affected by changes in both the conformer and solvation method with water being used as the solvent. Despite the noted changes, both vibrational transitions were determined to be within the range of 970-1100 cm-1 with the symmetric sulfonate stretch present at around 970-1010 cm-1 and the ether stretch observed at around 1050-1100 cm-1 with solvation present. While the calculated peak positions mirror those found in the experimental spectra within the literature, the traditional normal mode assignments do not match those predicted by our calculations. However, recent studies have hypothesized that these vibrational transitions are coupled, which could explain why they have been so difficult to assign. / Master of Science / Perfluorinated sulfonic acid (PFSA) ionomer membranes show great promise for use in proton exchange membrane fuel cells (PEMFCs) due to their excellent efficiency. However, the current techniques used to determine changes in structural configurations require sophisticated equipment and trained personnel to operate. Simpler techniques exist wherein the vibrations of certain bonds can be measured upon exposure of the sample to measured amounts of infrared light. The problem with this technique is that researchers currently do not fully understand at what wavelengths certain portions of the polymer known as functional groups will vibrate. These vibrations are also known as vibrational transitions. This study was undertaken to predict through numerical solutions to the Schrödinger equation at what wavelengths two particular vibrational transitions would occur for three common ionomers, Aquivion, 3M PFSA, and Nafion. For all three structures, the positions of these transitions mirrored that observed within the literature although the functional groups assigned to these positions did not match with those identified by our calculations. However, recent studies have indicated that these vibrational transitions occur at the same positions, which could explain why they have been so difficult to assign.

DFT

PFSA

PTFE

Ionomers

Aquivion

3M PFSA

Nafion

PEMFC

B3LYP

HF

M06

WB97XD

6-31+G*

6-311+G*

cc-pVDZ

AUG-cc-pVDZ

FTIR

Transmission

ATR