78 research outputs found
Proton location in acid⋯pyridine hydrogen bonds of multi-component crystals
YesThe design of new functional crystalline materials requires an understanding of the factors that control salt and co-crystal formation. These states often only differ in the location of the proton and are influenced by chemical and crystallographic factors. The interaction between a carboxylic acid and a pyridine is a frequently used supramolecular synthon in crystal engineering which can exist as either a co-crystal (CO2H⋯N) or salt (CO2−⋯HN+). The results of a Cambridge Structure Database search indicate that the nature of the functional groups on the pyridine play a stronger role in selection of the phase than those of the acid. However, the nature of the local hydrogen bonding of the interaction also adjusts the potential for proton transfer. This was demonstrated by ab initio modelling of the energy landscape for binary and ternary co-crystals by inclusion of varying components of the local environment
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Building up co-crystals: structural motif consistencies across families of co-crystals
YesThe creation of co-crystals as a route to creating new pharmaceutical phases with modified or defined physicochemical properties is an area of intense research. Much of the current research has focused on creating new phases for numerous active pharmaceutical ingredients (APIs) to alter physical properties such as low solubilities, enhancing processability or stability. Such studies have identified suitable co-formers and common bonding motifs to aid with the design of new co-crystals but understanding how the changes in the molecular structure of the components are reflected in the packing and resulting properties is still lacking. This lack of insight means that the design and growth of new co-crystals is still a largely empirical process with co-formers selected and then attempts to grow the different materials undertaken to evaluate the resulting properties. This work will report on the results of a combination of crystal structure database analysis with computational chemistry studies to identify what structural features are retained across a selection of families of co-crystals with common components. The competition between different potential hydrogen bonding motifs was evaluated using ab initio quantum mechanical calculations and this was related to the commonality in the packing motifs when observed. It is found while the stronger local bonding motifs are often retained within systems, the balance of weaker long-range packing forces gives rise to many subtle shifts in packing leading to greater challenges in the prediction of final crystal structures
Creation of a ternary complex between a crown ether, 4-aminobenzoic acid and 3,5-dinitrobenzoic acid
YesThe creation of ternary multi-component crystals through the introduction of 18-crown-6 to direct the hydrogen-bonding motifs of the other molecular components was investigated for 3,5-dinitrobenzoic acid (3,5-dnba) with 4-aminobenzoic acid (4-aba). The creation of a binary complex between 18-crown-6 and 4-aba (C12H24O6·2C7H7NO2)2 and a ternary salt between 3,5-dnba, 18-crown-6 and 4-aba (C12H24O6·C7H8NO2+·C7H3N2O6−·C7H4N2O6) were confirmed by single-crystal structure determination. In both structures, the amino molecules bind to the crown ether through N—H...O hydrogen bonds, leaving available only a single O atom site on the crown with restricted geometry to potentially accept a hydrogen bond from 3,5-dnba. While 3,5-dnba and 4-aba form a binary co-crystal containing neutral molecules, the shape-selective nature of 18-crown-6 preferentially binds protonated amino molecules, thereby leading to the formation of the ternary salt, despite the predicted low concentration of the protonated species in the crystallizing solution. Thus, through the choice of crown ether it may be possible to control both location and nature of the available bonding sites for the designed creation of ternary crystals
Poly(acrylic acid) interpolymer complexes
YesInterpolymer complex formation of poly(acrylic acid) with other macromolecules can occur via several mechanisms that vary depending on the pH. At low pH the protonated acid functional group can form bonds with both donor and acceptor moieties, resulting in desolvated structures consisting of two polymers. Complexes were formed in dilute solutions of PAA, functionalised with acenaphthylene, with a range of other polymers including: poly(NIPAM); poly(ethylene oxide) (PEO); poly(dimethylacrylamide) (PDMA); poly(diethyl acrylamide) (PDEAM) poly(vinyl alcohol) (PVA) and poly(vinyl pyrolidinone) (PVP). Fluorescence anisotropy was used to demonstrate complex formation in each case by monitoring the reductions in segmental motion of the chain as the complexes formed. Considerations of the molecular structures of the complexing moieties suggest that solvation energies and pKas play an important role in complex formation
Structural similarity in chiral-achiral multi-component crystals
YesThe creation of multi-component crystals between chiral and achiral components has gained increased interest in recent years. In many cases the overall crystal structure is similar with the creation of a pseudo-inversion centre in the enantiopure case. This allows for the formation of solid solutions between the two extremes, which may have applications within chiral resolution. Utilising a combination of database mining, computational prediction and experimental screening, the frequency of formation for such materials has been investigated showing that for co-crystals this occurs more frequently than for salts, though there is a limited number of samples to draw structural conclusions. Computational modelling indicates the prediction of such systems can be challenging due to the similarities in energy of many crystal structures, so development of tools to design such systems is required to fully utilise these concepts.The Deanship of Scientific Research at Princess Nourah bint Abdulrahman University through the Fast-track Research Funding Program
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Improving Stability of Effervescent Products by Co-Crystal Formation: A Novel Application of Crystal Engineered Citric Acid
YesThe major concern of the physical and chemical instability of effervescent products during manufacturing and storage is addressed through a co-crystallization strategy. Citric acid (CA) and sodium bicarbonate (SBC) are the essential components of effervescent products. CA is hygroscopic and led to an uncontrollable autocatalytic chain reaction with SBC in the presence of a small amount of moisture, causing product instability. The acid···amide dimer bond and layered structure of the citric acid-nicotinamide co-crystal restricts interaction of moisture with CA, making it nonhygroscopic, and improves the stability of effervescent products. The comparative study of effervescent products containing CA in its free form and as a co-crystal suggests a significant advantage of the use of co-crystal in effervescent products. This finding is supported by the mechanistic understanding developed through GAB and Y&N models obtained from moisture sorption data along with the computational investigations into moisture interactions with different crystal surfaces
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Investigation into the development of novel lanthanide-based luminescent colorants for application to textiles and paper materials
YesThis article describes the synthesis and application of lanthanide-based luminophores for visualisation under short wavelength ultraviolet (UV) activation (typically 254 nm). Luminophores are chemical compounds which re-emit light of longer wavelength than typical fluorescence and phosphorescence, following photoexcitation, because of efficient energy transfer from the ligands to the lanthanide ion emission levels. The luminophores described in this article are all derived from europium and terbium metal complexes and cover the complete colour gamut. Selection of appropriate ligands allows for water solubility or water insolubility (if required pigment or disperse “dye” applications). Similar to dyeing or printing processes, the anionic complexes can be applied to polyamide fibres or to cellulosic fibres, whereas dispersions of the non-ionic complexes are suitable for polyester or cellulose acetate fibre application. The water-soluble derivatives are also suitable for ink-jet printing and the water-insoluble derivatives are suitable for lithographic or intaglio paper printing. The novel complexes are excited by radiation below 300 nm and thus cannot be activated by sunlight (the earth's atmosphere prevents light below about 300 nm reaching the surface). Accordingly, the photo-stability of the dyed materials and prints obtained is excellent. These materials could be used in security marking applications, for example bank-notes and passports, where they could replace the current fluorophores that are rendered visible under near UV light (typically 365 nm) illumination but exhibit relatively poor photo-stability. The development of an RGB (red, green and blue) colour palette for inkjet printing based on these innovative luminophores will significantly support the design of digitally printed security features.The research was part funded by Inovink Ltd and theWorshipful Company of Clothworkers of the City of London
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Isostructurality of quinoxaline crystal phases: The interplay of weak hydrogen bonds and halogen bonding
YesTailoring the physical properties of molecular crystals though the construction of solid solutions requires the existence of isostructural crystals. Simple substitutions of a given molecular framework can give a range of different crystal structures. A set of quinoxaline derivatives, C8H4N2(C6H4X)2,Q3,3′X2, has been investigated (X = F, Cl, Br, I and Me) where kinetic factors generated a set of isostructural crystals for the lighter halogens (F, Cl, Br) alone. Computational analysis shows that the stabilising interactions are maximal for Cl, while DSC studies demonstrate the existence of more stable polymorphs for both F and Br containing systems. Steric factors appear to have a lower contribution than the balance of weaker hydrogen and halogen bonding shown by the Me and I containing systems displaying different packing driven by CH⋯N/CH⋯π bonds and I⋯I bonds respectively
Structural Motifs in Salts of Sulfathiazole: Implications for Design of Salt Forms in Pharmaceuticals APIs
YesThe creation of salts is a frequently used approach for the modification of physicochemical properties of an active pharmaceutical ingredient. Despite the frequency of application, there has been little research into the structural-property relationships of the final material and the nature of the counterion present. This work reports on five new salts of sulfathiazole and compares the energetics of the intermolecular interactions with variation in the crystal packing motifs
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