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The nucleation and growth of meta-aminobenzoic acid : a density functional theory and molecular dynamics studyGaines, Etienne January 2018 (has links)
Controlling crystal polymorphism, the ability of a molecule to crystallise in different solid forms, is one of the grand, ongoing challenges in materials science. In the pharmaceutical industry particularly, where up to half of the active pharmaceutical active ingredients exhibit polymorphic behaviour, it is of paramount importance to rationalise the impact of experimental conditions, such as the nature of the solvent, on the obtainment of a specific c crystal form. As strategies for the selection of polymorphs is still, by and large, based on a trial-and-error approach, it is necessary to acquire a fundamental understanding of the factors controlling the formation of a speci fic solid-state structure during crystallisation from solution. During this doctoral research project, we have conducted a computer simulation study of the early stages of crystallisation of meta-aminobenzoic acid, an important model system in the investigation of polymorphic phenomena. This molecule can in fact form five different polymorphic forms whose selective crystallisation from solution chiefly depends on the nature of the solvent. Molecular models and computational chemistry methods, based on density functional theory and molecular dynamics, have been developed and applied to quantify the processes surrounding the crystallisation of meta-aminobenzoic acid: solvent-solute separation, solute aggregation and surface reactivity. The aim was to identify what controls, at the molecular level, the polymorphic selection process during crystallisation from solution of this important active pharmaceutical ingredient. The results show that the solvent play a signi cant role during the key stages of meta-aminobenzoic acid crystallisation by controlling both the kinetics and thermodynamics of solute desolvation, formation of prenucleation clusters and surface reactivity. This work represents a paradigm of the role of molecular processes during the early stages of nucleation in affecting polymorph selection during crystallisation from solution.
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Crystal Polymorphism as a Probe for Molecular Self-Assembly during Nucleation from solutions: The Case of 2,6 - Dihydroxybenzoic Acid.Davey, R.J., Blagden, Nicholas, Righini, S., Alison, H., Quayle, M.J., Fuller, S. January 2001 (has links)
No / The relationship between molecular self-assembly processes and nucleation during crystallization from solution is an important issue, both in terms of fundamental physical chemistry and for the control and application of crystallization processes in crystal engineering and materials chemistry. This contribution examines the extent to which the occurrence of crystal polymorphism can be used as an indicator of the nature of molecular aggregation processes in supersaturated solutions. For the specific case of 2,6-dihydroxybenzoic acid a combination of solubility, spectroscopic, crystallization, and molecular modeling techniques are used to demonstrate that there is a direct link between the solvent-induced self-assembly of this molecule and the relative occurrence of its two polymorphic forms from toluene and chloroform solutions.
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Interactions Involving Organics Fluorine In Crystal Engineering : Insights From Crystal Packing And PolymorphismChaudhuri, Ansuman Ray 09 1900 (has links) (PDF)
No description available.
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Structure-Function Control in Organic Co-Crystals/Salts Via Studies on Polymorphism, Phase Transitions and Stoichiometric VariantsKaur, Ramanpreet January 2015 (has links) (PDF)
The thesis entitled “Structure-function control in organic co-crystals/salts via studies on polymorphism, phase transitions and stoichiometric variants” consists of five chapters.
The main emphasis of the thesis is on two aspects, one to characterize co-crystal polymorphism in terms of propensity of intermolecular interactions to form co-crystals/salts or eutectics. The other aspect is to explore the feasibility of using such co-crystals/salts to exhibit properties like proton conduction, dielectric and ferroelectric behaviour. Gallic acid and its analogues possess functionalities to provide extensive hydrogen bonding capabilities and are chosen as the main component while the coformers are carefully selected such that they either accept or reject the hydrogen bonding offered. Such co-crystallization experiments therefore provide an opportunity to unravel the intricate details of the formation of crystalline polymorphs and/or eutectics at the molecular level. Further these co-crystal systems have been exploited to evaluate proton conductivity, dielectric and ferroelectric features since the focus is also on the design aspect of functional materials. In the context of identifying and utilizing Crystal Engineering tools, the discussions in the following chapters address not only the structural details but identify the required patterns and motifs to enable the design of multi-component co-crystals/salts and eutectics. In particular, the presence/absence of lattice water in gallic acid has been evaluated in terms of importing the required physical property to the system.
Chapter 1 discusses the structural features of tetramorphic anhydrous co-crystals (1:1; which are synthon polymorphs) generated from a methanolic solution of gallic acid monohydrate and acetamide, all of which convert to a stable form on complete drying. The pathway to the stable form (1:3 co-crystal) is explained based on the variability in the hydrogen bonding patterns followed by lattice energy calculations.
Chapter 2A studies the presence/absence and geometric disposition of hydroxyl functionality on hydroxybenzoic acids to drive the formation of co-crystal/eutectic in imide-carboxylic acid combinations. In Chapter 2B the crystal form diversity of gallic acid-succinimide co-crystals are evaluated with major implications towards the design and control of targeted multi-component crystal forms. The co-crystal obtained in this study shows a rare phenomenon of concomitant solvation besides concomitant polymorphism and thus making it difficult to obtain a phase-pure
crystal form in bulk quantity. This issue has been resolved and formation of desired target solid form is demonstrated. Thus, this study addresses the nemesis issues of co-crystallization with implications in comprehending the kinetics and thermodynamics of the phenomenon in the goal of making desired materials.
Chapter 3 focuses on the systematic co-crystallization of hydroxybenzoic acids with hexamine using liquid assisted grinding (LAG) which show facile solid state interconversion among different stoichiometric variants. The reversible interconversion brought about by varying both the acid and base components in tandem is shown to be a consequence of hydrogen bonded synthon modularity present in the crystal structures analyzed in this context.
In Chapter 4A, the rationale for the proton conduction in hydrated/anhydrous salt/co-crystal of gallic acid - isoniazid is provided in terms of the structural characteristics and the conduction pathway is identified to follow Grotthuss like mechanism which is supplemented by theoretical calculations. Chapter 4B describes an extensive examination of the hydrated salt of gallic acid-isoniazid which unravels the irreversible nature of the dielectric property upon dehydration and suggests that the “ferroelectric like” behaviour is indeed not authenticated. This chapter brings out the significance role of lattice water in controlling the resulting physical property (dielectric/ferroelectric in this case).
Chapter 5 describes the structural features of two hydrated quaternary salts of hydroxybenzoic acids-isoniazid-sulfuric acid and the phase transitions at both low and high temperatures are shown to be reversible. Single Crystal to Single Crystal (SCSC) in situ measurement corroborated by thermal and in situ Powder X-ray Diffraction studies proves the claim. Further, the properties exhibited by these materials are also governed by lattice water content.
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