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Experimental and Computational Investigations of Chalcogen BondingMacDougall, Phillip January 2024 (has links)
Chalcogen bonding (ChB) is a particular case of secondary bonding centred on heavy group-16 elements. It is almost exclusively identified through crystallography by measuring interatomic distances intermediate between single-bond averages and the sum of van der Waals radii. However, there is significant recent progress in discerning its signatures using spectroscopic techniques such as multinuclear NMR.
This M.Sc. thesis describes progress in two research projects on chalcogen bonding. The first examined the effect of halogenation on the aggregation of 3-methyl-5-phenyl 1-2-tellurazole 2-oxide. The second examined the strengthening of ChB interaction between molecules of benzo-1,2-chalcogenazole 2-oxides by chlorination.
The bromination of 3-methyl-5-phenyl 1-2-tellurazole 2-oxide yielded 3,3,3-tri-bromo-3-methyl-5-phenyl-1,2-tellurazole-2-anole. Four unique crystal structures were obtained with the most promising being the dimeric structure. Deprotonation was unsuccessfully attempted although yielded 2 unique crystal structures co-crystallized with proton-sponge. Iodination of 3-methyl-5-phenyl 1-2-tellurazole 2-oxide was also performed, resulting in a mixed tetrameric aggregate containing two molecules of 3-methyl-5-phenyl 1-2-tellurazole 2-oxide and two 1,1-di-iodo-3-methyl-5-phenyl 1-2-tellurazole 2-oxide molecules. DFT investigations into the electronic properties, thermodynamics of aggregation, and basicity were performed. Similar to the chlorinated derivative, the most favourable aggregate to form is the hetero-tetramer with two brominated or iodinated molecules and 2 non-halogenated molecules.
The reaction of benzo 1,2-sellenazole 2-oxide with SO2Cl2 and benzo 1,2-tellurazole 2-oxide with HCl followed by SO2Cl2 yielded halogenated derivatives of each molecule in which the chalcogen was oxidized from Ch(II) to Ch(IV). In the selenium derivative, an unexpected chlorination occurred on the heterocycle of the molecule. Crystal structures were obtained for each chlorinated product where dimeric interactions were observed. DFT calculations show how the electronic and orbital mixing contributions to the ChB interactions are enhanced upon halogenation. Gibbs free energy of aggregation is most negative for a mixed structure in which two chlorinated molecules and two unchlorinated molecules are linked. / Thesis / Master of Science (MSc)
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Chemical Concepts and X-ray Technologies challenged by Charge DensitySchürmann, Christian Joseph 16 January 2019 (has links)
No description available.
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Orbital interactionsPascoe, Dominic James January 2018 (has links)
It is widely accepted that the sharing of electrons constitutes a bond. Conversely, molecular interactions that do not involve electron transfer, such as van der Waals forces and electrostatics are defined as "non-bonding" or "non-covalent" interactions. More recently computational and experimental observations have shown situations where the division between "bonding" and "non-bonding" interactions is blurred. One such class of interactions are known as σ-hole interactions. Chapter 1 provides a literature review of investigations into the nature of σ-hole interactions, highlighting the individual contributing factors. Chapter 2 provides a detailed analysis into the nature of chalcogen-bonding interactions. Synthetic molecular balances are employed for experimental measurements of conformational free energies in different solvents, facilitating a detailed examination of the energetics and associated solvent and substituent effects on chalcogen-bonding interactions. The chalcogen-bonding interactions examined were found to have surprisingly little solvent dependence. The independence of the conformational free energies on solvent polarity, polarisability and H-bond characteristics showed that electrostatic, solvophobic or dispersion forces were not dominant factors in accounting for the experimentally observed trends. A molecular orbital analysis provided a quantitative relationship between the experimental free energies and the molecular orbital energies, which was consistent with chalcogen-bonding interactions being dominated by an n→σ* orbital delocalisation. Chapters 3 and 4 both use the molecular orbital modelling approach established in Chapter 2 to investigate the potential partial covalency in H-bonding and carbonyl···carbonyl interactions. H-bonding is generally considered to be an electrostatically dominated interaction. However, computational results have suggested a partial covalent character in H-bonding. The molecular orbital analysis revealed an n→σ* electron delocalisation in all H-bonding systems evaluated. However, no quantitative correlation could be found with experimental free energies. Similarly, the nature of carbonyl···carbonyl interactions has been subject to debate, with electrostatic or an n→π* electron delocalisation having been proposed as the dominant factors. The molecular orbital analysis employed here showed that n→π* delocalisation was exceptionally geometry dependent. Studies of literature systems reveal that n→π* delocalisation contributes to overall stability of a range of systems, with a quantitative link between molecular orbital energy and conformational free energies.
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Unravelling the Nature of Halogen and Chalcogen Intermolecular Interactions by Charge Density AnalysisPavan, S January 2015 (has links) (PDF)
The thesis entitled “Unravelling the Nature of Halogen and Chalcogen Intermolecular Interactions by Charge Density Analysis" consists of five chapters. A basic introductory section describes the topics relevant to the work and the methods and techniques utilized. The main focus of the present work is to characterize the interaction patterns devoid of strong classical hydrogen bonds. The case studies include halogen bonds and hydrogen bonds involving bromine (as a halogen bond donor and hydrogen bond acceptor), intermolecular chalcogen bond formation involving sulphur, type I Br Br contacts, type II F F and F S interactions and S-H S hydrogen bonds.
Chapter 1 discusses experimental and theoretical charge density analyses on 2,2-dibromo-2,3-dihydroinden-1-one which has been carried out to quantify the topological features of a short C Br···O halogen bond with nearly linear geometry (2.922Å, C Br···O=172.7) and to assess the strength of the interactions using the topological features of the electron density. The electrostatic potential map indicates the presence of the “- hole” on bromine while the interaction energy is comparable to that of a moderate O-H O hydrogen bond. In addition, the energetic contribution of C-H···Br interaction is demonstrated to be on par with that of the C-Br···O halogen bond in stabilizing the crystal structure.
Chapter 2 discusses an organic solid, 4,7-dibromo-5,6-dinitro-2,1,3-benzothiadiazole that has been designed to serve as an illustrative example to quantitatively evaluate the relative merits of halogen and chalcogen bonding in terms of charge density features. The compound displays two polymorphic modifications, one crystall zing in a non-centrosymmetric space group (Z =1) and the other in a centrosymmetric space group with two molecules in the asymmetric unit (=2). Topological analysis based on QTAIM clearly brings out the dominance of chalcogen bond over the halogen bond along with an indication that halogen bonds are more directional compared to chalcogen bonds. The cohesive energies calculated with the absence of both strong and weak hydrogen bonds as well as stacking interaction are indicative of the stabilities associated with the polymorphic forms.
Chapter 3 discusses the role of a type I C-Br Br-C contact and what drives the contact i.e. how a dispersive interaction is stabilized by the remaining contacts in the structure. In the process we observe the role the Br2Cl motif which is quite unique in its nature. Also the role of the bromine atoms in stabilizing the stacking interactions has been shown by the electrostatic potentials which are oriented perpendicular to the plane of the benzene ring.
Chapter 4 discusses the enigmatic type II C-F F-C and C-FS-C interactions in pentafluorophenyl 2,2- bithiazole. Both the interactions are shown to be realistic “-hole” interactions based on high resolution X-ray charge density analysis. As fluorine is the most electronegative element, its participation in halogen bonding wherein the electrostatic potential around the atom gets redistributed to form regions of electron depletion and accumulation had time and again been speculated but never observed. In this chapter the experimental charge dnsity analysis clearly identifies the “-hole” on fluorine and distinguishes the C-F S-C interaction as a halogen bond rather than the chalcogen bond.
Chapter 5 discusses the experimental charge density analysis of the hitherto unexplored S-H S hydrogen bond in crystal structures. The work highlights how relatively small is the number of crystal structures which are constructed by the S-H S hydrogen bond compared to the X-H S hydrogen bond via Cambridge Structural Database (CSD) analysis. The potential S-H S hydrogen bond is studied in three isomeric mercaptobenzoic acids with experimental charge density collected on 2-mercaptobenzoic acid and theoretical estimates made on 3- and 4-mercaptobenzoic acid. The strength and directionality of the S-H S hydrogen bond is demonstrated to be mainly due to the conformation locking potential of intramolecular S O halogen bond.
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Analyse de la densité de charge et des propriétés topologiques des interactions intermoléculaires faibles - liaisons halogène et chalcogène - et leur comparaison avec des liaisons hydrogène / Charge density analysis and topological properties of weak intermolecular interactions ? halogen and chalcogen bonding - and their comparison with hydrogen bondingBrezgunova, Mariya 06 March 2013 (has links)
La compréhension et le contrôle des interactions intermoléculaires est d'une importance fondamentale dans les domaines de la reconnaissance moléculaire et de l'ingénierie cristalline, ainsi que dans les systèmes biologiques. Parmi les contacts faibles les plus fréquents qui lient les molécules dans les solides organiques nous trouvons la liaison halogène, la liaison chalcogène, et la liaison hydrogène faible. Dans cette thèse, des études expérimentales et théoriques de densité de charge rhô(r) basées sur la méthodologie QTAIM ont été effectuées pour l'analyse des liaisons halogènes et chalcogènes, et pour leur comparaison avec les liaisons hydrogène faibles. Pour ce faire, nous avons réalisé l'affinement multipolaire de la densité électronique obtenue à partir de la diffraction des rayons-X sur monocristal, ainsi qu'à partir des calculs périodiques DFT. A l'issue de nos résultats, nous avons définie la nature de ces interactions faibles (électrophile-nucléophile) et caractérisé leur intensité et directionnalité. Basé sur la topologie de L(r) = ¬rhô delta inversé2 rhô(r), le descripteur électrostatique (delta(L/rhô)) nous a permis d'évaluer quantitativement l'interaction électrostatique entre les régions de concentration (CC) et de dilution (CD) de charge de la couche de valence des atomes. L'énergie d'interaction (Eint) a été décrite à partir de descripteurs topologiques de rhô(r). Nous nous sommes intéressés également à la formation de fragments structuraux récurrents, appelés synthons. Il a été prouvé que le synthon peut être créé non seulement par des groupements d'atomes similaires, mais aussi par des ensembles de sites CC et CD qui sont impliqués de façon similaire dans la formation de contact / Understanding and control of intermolecular interactions play a crucial role in molecular recognition, crystal engineering, and biological systems. Three very frequent weak contacts linking the molecules in organic solids are halogen, chalcogen, and weak hydrogen bondings. In this thesis, we perform experimental and theoretical charge density rho(r) studies based on the QTAIM methodology for analyzing halogen and chalcogen bonding, and for comparing them with weak hydrogen bonding, as derived from the high-resolution single crystal X-ray diffraction multipole-refined electron density and from density functional theory (DFT) calculations. Defining the nature of these weak interactions as electrophilic-nucleophilic, we particularly focus on their strength and directionality. Based on the topology of L(r) = ¬rho inverted delta2 rho(r), a proposed electrostatic descriptor (delta(L/rho)) permitted us to evaluate quantitatively the electrostatic intensity between charge concentration (CC) and charge depletion (CD) regions belonging to the valence shell of the interacting atoms. The interaction energy (Eint) was described from the topological properties of rho(r). The attention has been also paid to the formation of recurrent structural fragments, called synthons. By the developed approach, it is proved that the synthon arrangement can be created not only by groups of atoms, but also by sets of CC and CD sites similarly involved in the contact formation
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Phase Behaviour in Crystalline Solids : Exploring the Structure Guiding Factors Via Polymorphism, Phase Transitions and Charge Density StudiesThomas, Sajesh P January 2013 (has links) (PDF)
The thesis entitled "Phase Behaviour in Crystalline Solids: Exploring the Structure Guiding Factors via Polymorphism, Phase Transitions and Charge Density Studies"
consists of five chapters divided into two parts. A basic introductory section describes the topics relevant to the work and the methods and techniques utilized. Part A contains two chapters that discuss the structural aspects related to polymorphism, solvatomorphism, conformational preferences and phase transitions exhibited by active pharmaceutical ingredients (APIs). It also discusses the structure-property correlations in API crystal forms and the possible utility of second harmonic generation (SHG) for their bulk characterization. Part B has three chapters that discuss experimental and theoretical charge density analyses of intra-and intermolecular interactions that play structure guiding roles in some of the APIs discussed in Part A. The main focus of the present work is to characterize the interaction patterns devoid of strong classical hydrogen bonds. The case studies include multifurcated C - H …O hydrogen bonds, the “carbon bonding” and chalcogen interactions involving Se and S atoms. In addition to charge density studies, in situcryocrystallography and molecular complexation experiments have been employed to examine structural consequences of chalcogen bonding. Further, Appendices 1 and 2 describe phase transition studies on the inorganic mineral kröhnkite and its high temperature phase transitions leading to novel inorganic structural types.
Part A: Polymorphism and phase behaviour in Active Pharmaceutical Ingredients (APIs)
Chapter 1 discusses case studies of polymorphism, supramolecular preference sand phase transitions exhibited by active pharmaceutical ingredients (APIs). Section 1.1 deals with the polymorphism of an anti-oxidant drug candidate ebselen and its hydroxyl derivative. The potential of organoselenium compounds to form a Se…O chalcogen bonded supramolecular recognition unit (synthon) has been established in these polymorphs and its generality is substantiated with the help of a Cambridge Structural Database (CSD) analysis. Section 1.2 demonstrates the utility of the ‘chalcogen bonded supramolecularsynthon’ in generating molecular complexes of APIs. A series of salts and co-crystals of the amyotrophic lateral sclerosis drug Riluzole have been synthesized in order to evaluate the structure directing role of S…O chalcogen bonded synthon in their crystal structures. Section 1.3adescribes the generation of polymorphs and solvatomorphs of the antidepressant drug candidate fenobamand associated phase transitions. The tautomeric preference in this molecule has been rationalized from the crystal structure analysis and abinitioenergy calculations. Further, section 1.3b utilizes chemical derivatization as a means to experimentally simulate thetautomeric preference and molecular conformations in several derivatives of fenobam and thiofenobam. Section 1.4 describes the issue of solvatomorphism and the generation of the fifth solvatomorph of gallic acid, its structural complexity and temperature induced phase transitions. The ability of solvent water molecules to drive structural diversity, by forming ‘hydration synthons’,is demonstrated in this case. Chapter 2 presents a novel methodology for the detection of polymorphic impurities in APIs based on second harmonic generation (SHG).The SHG based method has been employed to polymorphic mixtures of fenobam, hydrochlorothiazide, pyrazinamide, tolbutamide, curcumin, febuxostat and nimesulide.The conventional methods such as powder X-ray diffraction (profile fitting analysis), FT-IR, Raman spectroscopy and thermal analysesto detect the presence of polymorphic impuritiesin bulk API samples are employed on the mixtures of these API samples and the impurity detection limits are compared with the proposed SHG methodology. The APIs used in these case studies were screened for their SHG efficiency using quantum chemical calculations of hyperpolarizability and HOMO-LUMO charge redistribution behaviour. Further, a correlation with the crystal symmetry, relative packing arrangement of molecules and the observed SHG efficiency have been discussed in of some of these cases.
Part B: Exploring the nature and structural consequences of nonbonding interactions in molecular crystals
Chapter 3 discusses the electron density features of quasi-trifurcated CH…Cl/CH…O interaction motifs leading to ‘carbon bonding’ and a trifurcated CH…O hydrogen bond motif. Section 3.1 describes the experimental and theoretical charge density analyses of quasi-trifurcated CH…Cl and CH…O motifsand investigates the existence of “carbon bonding” in solid state. The experimental charge density evidence for “carbon bonding” have been analyzed in cases of fenobam and dimethylamine: 4-hydroxybenzoic acid complex. The existence of this unconventional interaction, which roughly mimics the transition state geometry of SN2 (bimolecular nucleophilic substitution) reaction, is further established by a CSD analysis. Section 3.2 describes the experimental and theoretical charge density analyses of ferulic acid and compares the topological features associated with a trifurcated CH…O hydrogen bond motif, with corresponding strong classical OH…O hydrogen bonds. The study demonstrates the “Gulliver effect” of weak interactions in charge density terms. Charge density based interaction energy calculations via EPMM and EML methods have been utilized in this context to evaluate the relative strength of such interactions. Chapter 4 discusses the charge density features of intermolecular chalcogen bonding interactions involving selenium and sulphur atoms.Section 4.1 describes the experimental and theoretical charge density analyses of ebselen and its hydroxyl derivative. The charge density characterization of the conserved chalcogen bond synthon (discussed in chapter 1, section 1.1) has been carried out and electronic nature and geometric dependence of Se…O interactions have been explored. The mechanism of drug action of ebselen has been correlated with the experimentally observed charge density distribution around the intramolecular SeC and SeN bonds. Section 4.2 explores the homochalcogen interactions such as S…SandSe…Se in phenol analogues. In situ cryocrystallographic studies on thiophenol, selenophenol and their solid solutions are described. Veggard’s law-like behaviour observed in these solid solutions have been rationalized and the S…S and Se…Sehomochalcogen interactions have been evaluated in these liquid systems which are devoid of any other packing forces such as strong hydrogen bonds. Chapter 5 discusses the conformation locking potential of intramolecular S…O chalcogen bonding in sulfadrugs. Section 5.1 discusses conformation locking in the antibioticdrugsulfamethizole. A two pronged approach has been adopted in the study; a) generation of cocrystals and salts of sulfamethizole for the ‘experimental simulation’ of the molecular conformation, b) evaluation of charge density distribution around the intramolecular S…O interaction region in sulfamethizole. Section 5.2 describes the effect of ‘simple hybridized orbital geometry’ in the formation of intramolecular S…O chalcogen bonding. The experimental charge density analysis of the carbonic anhydrase inhibitor drug acetazolamide has been carried out and the two different intramolecular S…O geometries have been compared in terms of the charge density topology. The analysis highlights the advantage of “orbital geometry” consideration over the conventional distance-angle criteria in assessing nonbonded interactions.
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