Global ETD Search

1	Switches based on crown ethers, cyclophanes and amino acids Moody, T. S. January 2001 (has links) No description available. 547 Crystal packing
2	Aspects of the crystal chemistry of organic acid-amides King, John January 1994 (has links) No description available. 547 Crystal packing; Hydrogen bonding
3	Solvatomorphism of Reichardt's dye Pike, Sarah J., Bond, A.D., Hunter, C.A. 20 February 2020 (has links) Yes / A systematic study of the influence of solvent on the crystal packing behaviour of Reichardt's dye demonstrates that the structure of the assembly formed in the solid state depends on the nature of the solvent–solute interactions present in the solution phase. Apolar aprotic solvents lead to solvates with a hexagonal channel topology, but this supramolecular assembly is perturbed by the presence of aromatic or polar protic solvents. Reichardt's dye Crystal packing behaviour Solvent Solvatomorphism
4	The prediction of the crystal packing of organic molecular solids Zaniewski, Rebecca Cecily January 1995 (has links) No description available. Chemistry, Physical Crystal packing Organic molecules
5	STUDIES OF UNUSUAL PACKING AND OF POLYMORPHISM IN TWO CRYSTAL SYSTEMS Hao, Xiang 01 January 2005 (has links) Crystal structures of anhydrous pinacol, the hexagonal pinacol, pinacol monohydrate, and pinacol hexahydrate were studied. In all the structures crystal packing is unusual and complicated. The origin of the complexity may be the difficulty in filling space densely and while also satisfying the H-bonding requirements when the molecule has few internal degrees of freedom. Five 15-crown-5 complexes of M(NO3)2 (M = Cu, Zn, Mg, Co, Mn) were synthesized and characterized using X-ray diffraction and differential scanning calorimetry. The system is rich in polymorphs. Nine definite solid-state phases were identified. More phases probably exist in the solid state at temperatures slightly above the room temperature. Most phase transformations in this system take place in single crystals without the loss of crystallinity. The nine phases crystallize in five crystal structures. The crown ether ligands have very similar conformation in all the structures. The asymmetric units in all the structures are complicated and pseudosymmetric, which is the consequence of the presence of the packing problem. The origin of the packing problem that leads to the complicated phase behavior is the odd number of -CH2-O-CH2- units in the crown ether ligand. Chemistry
6	SYNTHESIS AND DEVICE CHARACTERIZATION OF FUNCTIONALIZED PENTACENES AND ANTHRADITHIOPHENES Subramanian, Sankar 01 January 2008 (has links) Research on pi-conjugated organic materials in the recent past has produced enormous developments in the field of organic electronics and it is mainly due to their applications in electronic devices such as organic field effect transistors (OFETs), organic light emitting diodes (OLEDs) and organic photovoltaic cells (OPVs). The primary goal of this research work is to design and synthesize high performing charge transport organic semiconductors. One of the criteria for better performance of the organic thin film transistor (OTFT) is to have high uniform thin film morphology of the organic semiconductor layer on the substrate. The first project in this dissertation has been directed towards improving the thin film morphology of the functionalized pentacenes through liquid crystalline behaviour. The results have suggested the possibility of thermotropic liquid crystalline phases in 6,13-bis(diisopropylhexylsilylethynyl) pentacene which has no pi-stacking in its solid state and the presence of silyl group at the peri-position is crucial for the stability of the functionalized pentacenes. In the second project, i have investigated the effect of alkyl groups with varying chain length on the anthradithiophene chromophore on the performance of the charge transporting devices. Organic blend cell based on solution processable 2,8-diethyl-5,12-bis(triethylsilylethynyl) anthradithiophene has showed 1% power conversion efficiency and the performance is mainly attributed to the large crystalline phase segregation of the functionalized anthradithiophene from the amorphous soluble fullerene derivative matrix. OTFT study on alkyl substituted functionalized anthradithiophenes suggested the need of delegate balance between thin film morphology and the crystal packing. Third project has been directed towards synthesizing halogen substituted functionalized anthradithiophenes and their influence in the performance of OFETs. OTFT made of 2,8-difluoro-5,12-bis(triethylsilylethynyl) anthradithiophene produced devices with thin film hole mobilities greater than 1 cm2/Vs. The result suggested that the device is not contact limited rather this high performance OTFTs are due to the contact induced crystallinity of the organic semiconductor.
7	NOVEL SOLUTION PROCESSABLE ACCEPTORS FOR ORGANIC PHOTOVOLTAIC APPLICATIONS Shu, Ying 01 January 2011 (has links) The field of organic electronics has become an increasingly important field of research in recent years. Organic based semiconductors have the potential for creating inexpensive, solution processed devices on flexible substrates. Some of the applications of organic semiconductors include organic field effect transistors, organic light emitting diodes and organic photovoltaics. Functionalized pentacenes have been proven to be viable donor materials for use in organic photovoltaic devices. The goal of this research is to synthesize and test the viability of novel electron deficient pentacenes and pentacene based materials as acceptors to be used as drop-in replacements for PCBM in bulk-heterojunction organic solar cells. Our goal was to tune and improve the efficiencies of these solar cells in a two pronged approach. First we tuned the open circuit voltage of these devices by determining the optimal energy levels of these acceptors by varying the number of electron withdrawing substituents on the acene core. We also tuned the short circuit current by chemically altering the solid state packing and optimizing device processing conditions. A preliminary structure-property relationship of these small molecule acceptors and photovoltaic device efficiency was established as a result. organic solar cells thin film morphology crystal packing pentacenes acenofullerenes n-type Chemistry
8	NEW PHOTOVOLTAIC ACCEPTORS: SYNTHESIS AND CHARACTERIZATION OF FUNCTIONALIZED C-FUSED ANTHRADITHIOPHENE QUINONES Shelton, Kerri 01 January 2011 (has links) Stable organic semiconductors are critical to produce inexpensive, efficient and flexible thin film organic solar cells. A current chemical focus is the synthesis of stable, electron-accepting materials to be utilized as an acceptor layer in photovoltaics.1 The Anthony group has shown that the functionalization of pentacene with suitable electron withdrawing groups provides a catalog of suitable acceptors for this purpose.2 These pentacenes can be further modified to pack in a unique 1-dimensional "sandwich herringbone" crystal packing, leading to improved device current.3 To improve the stability of acene acceptors, we have taken two hetero-atom themed approaches. First, we have studied the acenequinone as an electron-accepting chromophore.4 Further, we replaced the terminal aromatic rings with heterocycles, such as furan or thiophene. In order to enhance the crystal engineering versatility of the chromophore, we utilize c-fused heterocycles (rather than the more commonly used b-fused cycles seen in e.g. anthradithiophenes). The c-fused acenequinones can be tetra-functionalized with silylethynyl groups to influence crystal packing and increase solubility.5 The silylethyne groups are known to increase the photostability and lower the energy gap (Eg) of pentacenes.5 The functionalization of the silylethyne groups also aids in lowering the lowest unoccupied orbital (LUMO) of acene structures.5 organic solar cells thin film morphology crystal packing anthradithiophene quinones n-type Chemistry
9	Molecular Dynamics Simulation of the Effect of the Crystal Environment on Protein Conformational Dynamics and Functional Motions Ahlstrom, Logan Sommers January 2012 (has links) Proteins are dynamic and interconvert between different conformations to perform their biological functions. Simulation methodology drawing upon principles from classical mechanics - molecular dynamics (MD) simulation - can be used to simulate protein dynamics and reconstruct the conformational ensemble at a level of atomic detail that is inaccessible to experiment. We use the dynamic insight achieved through simulation to enhance our understanding of protein structures solved by X-ray crystallography. Protein X-ray structures provide the most important information for structural biology, yet they depict just a single snapshot of the solution ensemble, which is under the influence of the confined crystal medium. Thus, we ask a fundamental question - how well do static X-ray structures represent the dynamic solution state of a protein? To understand how the crystal environment affects both global and local protein conformational dynamics, we consider two model systems. We first examine the variation in global conformation observed in several solved X-ray structures of the λ Cro dimer by reconstructing the solution ensemble using the replica exchange enhanced sampling method, and show that one X-ray conformation is unstable in solution. Subsequent simulation of Cro in the crystal environment quantitatively assesses the strength of packing interfaces and reveals that mutation in the lattice affects the stability of crystal forms. We also evaluate the Cro models solved by nuclear magnetic resonance spectroscopy and demonstrate that they represent unstable solution states. In addition to our studies of the Cro dimer, we investigate the effect of crystal packing on side-chain conformational dynamics through solution and crystal MD simulation of the HIV microbicide Cyanovirin-N. We find that long, polar surface side-chains can undergo a strong reduction in conformational entropy upon incorporation into crystal contacts, which supports the application of surface engineering to facilitate protein crystallization. Finally, we outline a general framework for using network visualization to aid in the functional interpretation of conformational ensembles generated from MD simulation. Our results will enhance the understanding of X-ray data in establishing protein structure-function-dynamics relationships. lambda Cro dimer molecular dynamics simulation network visualization protein X-ray structures Chemistry conformational dynamics crystal packing
10	Third Generation Crystal Engineering : Supramolecular Synthons, IR Spectroscopy and Property Design Saha, Subhankar January 2017 (has links) (PDF) Crystal engineering is defined as “the understanding of intermolecular interactions in the context of crystal packing and in the utilisation of such understanding in the design of new solids with desired physical and chemical properties”. If crystals are the supramolecular equivalents of molecules, then crystal engineering is the supramolecular equivalent of organic synthesis. The subject considers both crystal structure analysis and design of new structures with targeted properties. The concept of “Supramolecular Synthons” was introduced by G. R. Desiraju in this context, for the rational design of structures. Supramolecular synthons are the smallest reducible structural units that contain geometrical and chemical information required for recognition between functional groups in molecular solids. Crystal engineering has grown very fast after the introduction of this idea in 1995 and engineered solids were found to be useful for application in many diverse fields, from structural chemistry to drug design. Because of the great significance of supramolecular synthons, their identification and analysis in terms of crystallographic, spectroscopic, and computational methods is essential. Single crystal X-ray diffraction (SCXRD) is a widely used technique for the identification of synthon structure. But the technique has its own limitations like requirement of good quality, suitably sized single crystals, longer times associated with the process which further restricts high throughput analysis. Practically, there is no other way for identification of synthons on a regular basis. In this situation a simple, accurate, and fast method will be of significance; not only for basic studies, but also to scan different solid state phases in pharmaceutical industries. Due to this reason, I have studied IR spectroscopy to find marker bands for different synthons in the first part of the thesis. In chapter 2, I have analyzed a variety of C–H···X based weak synthons. For identification of each synthon, two sets of compounds were taken. In one set the synthon exists and in the other set it does not. Comparison and verification of IR characteristics helps to establish marker bands. Such markers are used to get information on synthon patterns in compounds with unknown crystal structures. The next challenge is whether or not such an IR method can distinguish different geometries of a same interaction. To address this question, different geometries of NO2···I halogen bonded synthons are investigated in chapter 3. This synthon exists in three geometries P, Q and R based on angular and distance criteria. The identification process is divided into five steps. The first step identifies IR signatures from very similar compounds, but with different topologies. The second step verifies earlier features and establishes IR marker bands. In the next step a graded IR protocol is formulated for stepwise discrimination of unknown systems. Such a graded method is applied for clarification of synthon ambiguities and in the identification of synthons in new compounds. Till now synthon information from crystal structures is used as a basis for IR study. Spectroscopy provides chemical information on intermolecular interactions. Is it possible to use such chemical information for crystal engineering? Chapter 4 deals with this aspect. Here, IR investigation is performed on the acid···amide heterodimer synthon. The initial analysis shows contradictory outcomes for synthon formation. According to IR, the N–H···O interaction is significantly destabilized in this synthon. Why then does the acid···amide synthon form? It is found that the answer lies in the higher stability of the other interaction, O–H···O, in the synthon. In other words, dimer formation will be preferred when the O‒H···O interaction is favoured. This is possible when the acidity of H-atom and the basicity of carbonyl O-atom is high. Based on this, a combinatorial study is performed varying the chemical nature of molecules, electron donating or withdrawing. Four quadrants are generated with different combinations of the molecular nature. The result of the combinatorial study shows different acid–amide oriented synthon preferences from different quadrants. A combination of all the observed synthons creates a structural landscape for the acid–amide system. A particular synthon associated with a specific quadrant is found to be responsible for the mechanical property of the synthesized cocrystals. Analysis on the structural aspects of mechanical properties allows for the formulation of models for property engineering. Can it be possible to use these models for targeted property design, other than serendipitous results? Crystal engineering is associated with three aspects, structure analysis, structure design and property engineering. Structure analysis is the first step in any crystal engineering exercise. It also explains the way by which the subject was started in the early days to correlate structure with property. This is the first phase or generation of crystal engineering. The second generation considers rational design of crystal structure which is facilitated by the concept of the supramolecular synthon. This phase has seen in the incorporation of different synthon based strategies to build a variety of supramolecular architectures. However, there is no prediction of a property which is the ultimate aim of crystal engineering. If one can achieve a desired property by predesign, then crystal engineering will see the final and higher stage which is termed third generation crystal engineering in chapter 5. The second part of the thesis discusses work is this direction, where mechanical properties are targeted and achieved by design using models from previous work. Chapter 6 discusses the engineering of elastic crystals from initial brittle precursors. A capping based model is proposed and used to prepare systems that can adopt the desired structure type. Among many other requirements, the crystals need some structurally buffering regions to show elasticity. Type-II electrostatic halogen bonds are used to construct such buffering regions. When the crystals are obtained according to the model type, they show reversible elastic deformation. σ-Hole based halogen bonds are crucial to the synthesis. But, during the project some adverse effects were noticed/realized for the use of halogen bonds. This suggests the need for an alternative methodology. A synthon that can mimic both the geometrical and chemical nature of σ-hole based halogen bonds would be useful to replace the earlier one. A search in this respect results in π-hole oriented orthogonal synthons based on C=O···C=O and NO2···NO2 interactions. A stepwise replacement procedure is applied to see and carry forward structural modularity in the new systems. Cocrystal systems are chosen for easy replacement by changing the constituents. Halogen bonds in cocrystals of the first step are partially substituted by a π-hole mimicking synthon in the second step and completely substituted in the third step. All the structures in the different steps are found to retain the same property, namely elasticity, although they possess dissimilar synthons. These aspects are discussed in chapter 7. Chapter 8 deals with the design of hand twistable helical crystals which are known to result during natural growth. Helical shape crystals are highly impactful for application in metamaterials and lithographic techniques, but at the same time occurrence of such morphology is unpredictable. Such shape generates from the periodic bending of crystals and thus needs multiple deformation directions. Here, a multistep crystal engineering procedure is adopted to get two directionally (2D) plastically bendable crystals, starting from one directional (1D) plastic crystals. Halogen bonds again play a major role in the design. The route follows the order 1D plastic crystals → 1D elastic crystals → 2D elastic crystals → 2D plastic crystals. These 2D plastic crystals are used to obtain hand-twisted helical crystals. Here, different properties namely elastic and plastic are seen in identically structured compounds. Once again, problems in using halogens are noticed. To address the issue of halogens, chapter 9 uses halogen bond/hydrogen bond equivalence to replace halogen bonds by geometrically and chemically similar hydrogen bonds. However, the first designed molecule in this respect did not result in the desired structure. The obligations are removed by applying the molecular/supramolecular equivalence strategy on the earlier molecule. Such an attempt gives another completely hydrogen bonded system that can now adopt the model structure and show a similar 2D plasticity. Crystals of this compound are also hand twistable. Third generation crystal engineering needs predesign models for targeted property engineering. In this context some differently structured elastic crystals are compared with common brittle crystals to identify and ascertain the structural requirements. This analysis helps in constructing different models for future engineering of elastic crystals. It also tabulates the structural and interaction differences in obtaining different mechanical properties namely shearing, plastic, elastic and brittle. In summary, these two major aspects for doing crystal engineering are highlighted in my thesis. One is the identification of robust synthons and the other is the use of synthon based structure design for property engineering. The first part of the thesis discusses the IR spectroscopic method for identification of synthons and then uses the spectral information for crystal structure engineering. The second part is related to deliberate crystal property engineering and uses structure-property relationships from the previous chapters and the literature to formulate predesign models and strategy. Achieving crystal properties in this way is expected to initiate the fast progress of the third generation crystal engineering. Crystal Engineering Supramolecular Synthons IR Spectroscopic Signatures Elastic Crystals Engineering Acid-amide System - Crystal Structure Crystal Property Engineering Crystal Packing Analysis Crystal Structure Design Helical Crystals IR Filters Elastic Crystals Brittle Crystals Solid State and Structural Chemistry

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