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The Crystal Polymorphism of Tetrolic Acid (CH3C=CCOOH): A Molecular Dynamics Study of Precursors in Solution, and a Crystal Structure Generation (1997)

Gavezzotti, A. ; Filippini, G. ; Kroon, J. ; [et al.]

Weinheim : Wiley-Blackwell

Chemistry - A European Journal 3 (1997), S. 893-899

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ISSN: 0947-6539

Keywords: crystal structure predictions ; molecular dynamics ; polymorphism ; tetrolic acid ; Chemistry ; General Chemistry

Source: Wiley InterScience Backfile Collection 1832-2000

Topics: Chemistry and Pharmacology

Notes: The possible configurations of two molecules of tetrolic acid in a solvent box containing 226 carbon tetrachloride molecules are studied by molecular dynamics with the GROMOS package and force field over periods of up to 2000 picoseconds. The cyclic hydrogen-bonded dimer was the most persistent configuration, but events leading to the cleavage of one hydrogen bond and thus the formation of a precursor to the crystal catemer motif were found to occupy up to 10% of the simulation times. The experimental bond-breaking enthalpy was correctly reproduced. Two different crystal structure generation procedures were employed to reproduce the two observed polymorphic crystal structures and to predict other possible polymorphs; in all cases, some unobserved structures had more cohesive packing energies than the observed ones. The possible application of molecular dynamics in the study of the preliminary steps in crystal nucleation is discussed.

Additional Material: 7 Ill.

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1002/chem.19970030610

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The crystal and molecular structures of cellulose I and II (1997)

Kroon-Batenburg, L.M.J ; Kroon, J

Springer

Glycoconjugate journal 14 (1997), S. 677-690

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ISSN: 1573-4986

Keywords: molecular dynamics ; crystal structure ; cellulose I and II

Source: Springer Online Journal Archives 1860-2000

Topics: Chemistry and Pharmacology

Notes: Abstract The paper describes molecular dynamics (MD) simulations on the crystal structures of the Iβ and II phases of cellulose. Structural proposals for each of these were made in the 1970s on the basis of X-ray diffraction data. However, due to the limited resolution of these data some controversies remained and details on hydrogen bonding could not be directly obtained. In contrast to structure factor amplitudes in X-ray diffraction, energies, as obtained from MD simulations, are very sensitive to the positions of the hydroxyl hydrogen atoms. Therefore the latter technique is very suitable for obtaining such structural details. MD simulations of the Iβ phase clearly shows preference for one of the two possible models in which the chains are packed in a parallel orientation. Only the parallel-down mode (in the definition of Gardner and Blackwell (1974) J Biopolym 13: 1975-2001) presents a stable structure. The hydrogen bonding consists of two intramolecular hydrogen bonds parallel to the glycosidic linkage for both chains, and two intralayer hydrogen bonds. The layers are packed hydrophobically. All hydroxymethyl group are positioned in the tg conformation. For the cellulose II form it was found that, in contrast to what seemed to emerge from the X-ray fibre diffraction data, both independent chains had the gt conformation. This idea already existed because of elastic moduli calculations and 13C-solid state NMR data. Recently, the structure of cellotetraose was determined. There appear to be a striking similarity between the structure obtained from the MD simulations and this cellotetraose structure in terms of packing of the two independent molecules, the hydrogen bonding network and the conformations of the hydroxymethyl group, which were also gt for both molecules. The structure forms a 3D hydrogen bonded network, and the contribution from electrostatics to the packing is more pronounced than in case of the Iβ structure. In contrast to what is expected, in view of the irreversible transition of the cellulose I to II form, the energies of the Iβ form is found to be lower than that of II by 1 kcal mol-1 per cellobiose.

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1023/A:1018509231331

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