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Ab initio study of structure and interconversion of native cellulose phases.

Ab initio study of structure and interconversion of native cellulose phases. Dispersion-interaction corrected DFT simulations are performed to study the structure of two allomorphs of native cellulose I. Good agreement between theoretical and experimental data is achieved. Two H-bond patterns, previously identified experimentally, are examined for both allomorphs. The transition mechanism for the conversion between the phase I(α) and I(β) is studied by means of constrained relaxations. New metastable intermediate phase occurring on the I(α) → I(β) route is identified, and the corresponding structural data are reported. http://www.deepdyve.com/assets/images/DeepDyve-Logo-lg.png The Journal of Physical Chemistry A Pubmed

Ab initio study of structure and interconversion of native cellulose phases.

The Journal of Physical Chemistry A , Volume 115 (35): -9991 – Jan 3, 2012

Ab initio study of structure and interconversion of native cellulose phases.


Abstract

Dispersion-interaction corrected DFT simulations are performed to study the structure of two allomorphs of native cellulose I. Good agreement between theoretical and experimental data is achieved. Two H-bond patterns, previously identified experimentally, are examined for both allomorphs. The transition mechanism for the conversion between the phase I(α) and I(β) is studied by means of constrained relaxations. New metastable intermediate phase occurring on the I(α) → I(β) route is identified, and the corresponding structural data are reported.

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ISSN
1089-5639
DOI
10.1021/jp205827y
pmid
21800863

Abstract

Dispersion-interaction corrected DFT simulations are performed to study the structure of two allomorphs of native cellulose I. Good agreement between theoretical and experimental data is achieved. Two H-bond patterns, previously identified experimentally, are examined for both allomorphs. The transition mechanism for the conversion between the phase I(α) and I(β) is studied by means of constrained relaxations. New metastable intermediate phase occurring on the I(α) → I(β) route is identified, and the corresponding structural data are reported.

Journal

The Journal of Physical Chemistry APubmed

Published: Jan 3, 2012

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