Origin of the twist of cellulosic materials

•Calculations show single cellulose chains twist away from a flat ribbon conformation independent of degree of polymerization and water solvation.•The twisted structure has multiple periodicites, which suggests a possible method of propagation to the macroscopic scale.•Energy minimization of cellulo...

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Bibliographic Details
Published in:Carbohydrate polymers 2016-01, Vol.135, p.285-299
Main Authors: Conley, Kevin, Godbout, Louis, Whitehead, M.A. (Tony), van de Ven, Theo G.M.
Format: Article
Language:English
Subjects:
Cellulose - chemistry
Cellulose conformation
Computational Chemistry
Crystallization
Helical chirality
Molecular Conformation
Powder Diffraction
Twist of Cellulose
X-Ray Diffraction
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Summary:•Calculations show single cellulose chains twist away from a flat ribbon conformation independent of degree of polymerization and water solvation.•The twisted structure has multiple periodicites, which suggests a possible method of propagation to the macroscopic scale.•Energy minimization of cellulose crystallites distorts the crystals into twisted rods. The degree of twist of the crystal is dependent on the cross-section of the crystal.•When solvated with water, the handedness of the twist of small crystals can reverse suggesting small crystals will spontaneously solubilize.•Simulated powder X-ray diffraction suggest small crystals lose crystallinity. Molecular Mechanics, Hartree–Fock, and semi-empirical geometry optimizations were carried out on cellulose oligomers and crystallites with and without water solvation. The intramolecular bonding is visualized with the Delocalized Molecular Orbitals (DLMOs). Internal coordinates were relaxed and the structures were gradient optimized for cellulose oligomers composed of 4, 10, 12, 14, 19, and 65 glucose units. The cellulose conformation of minimum energy deviates from the flat ribbon conformation giving rise to half-twist repeating units of about 3–4nm and 60nm along the chain axis. An optimized cellulose chain which is ten glucose units long is 9.57kcal/mol more stable than the flat ribbon model. The DLMOs show the twisted model retains the same hydrogen bonding scheme as the flat model while minimizing steric interactions between H1 and H4′. In cellulose crystallites the twist, which can be left- or right-handed, calls into question the assumption of twofold symmetry in the current flat unit cell. Additionally the hydrogen bonded sheets reorient themselves, suggesting the crystallites are in fact crystalloids. The overall length of the crystal twist is dependent on the cross-section of the crystal. Powder X-ray diffraction patterns of the optimized crystallites were simulated.
ISSN:0144-8617
1879-1344
DOI:10.1016/j.carbpol.2015.08.029