The structure of celluloses

Masahisa Wada; Yoshiharu Nishiyama; Henri Chanzy; Trevor Forsyth; Paul Langan

doi:10.1154/1.2912442

The structure of celluloses

Masahisa Wada, Yoshiharu Nishiyama, Henri Chanzy, Trevor Forsyth, Paul Langan

Research output: Contribution to journal › Article › peer-review

35 Scopus citations

Abstract

X-ray and neutron fiber diffraction has been used to study cellulose as it is converted from its naturally occurring crystal phase, cellulose I, to an activated crystal phase, cellulose IIII, by ammonia treatment. The detailed crystal structures determined for cellulose IΒ, an intermediate ammonia-cellulose I complex, and cellulose IIII, reveal a structural transition pathway: hydrogen bonded sheets of chains in cellulose IΒ slip with respect to each other to accommodate the penetrating ammonia guest molecules in the intermediate complex. On evaporation of ammonia from the intermediate complex, there is a relative small change in chain packing as an inter-sheet ammonia bridge is replaced by an inter-sheet hydrogen bond in cellulose IIII. When cellulose IIII is heated it converts back to cellulose IΒ. Both ammonia-cellulose I and cellulose IIII have extended chains of cooperative hydrogen bonds in relatively open crystal structures that may add to their susceptibility to rapid change.

Original language	English
Pages (from-to)	92-95
Number of pages	4
Journal	Powder Diffraction
Volume	23
Issue number	2
DOIs	https://doi.org/10.1154/1.2912442
State	Published - 2008
Externally published	Yes

Keywords

Cellulose
Fiber
Hydrogen bond
Neutron crystallography
X-ray crystallography

Access to Document

10.1154/1.2912442

Cite this

@article{b1e71cace115477fa44191a0a98f5c46,

title = "The structure of celluloses",

abstract = "X-ray and neutron fiber diffraction has been used to study cellulose as it is converted from its naturally occurring crystal phase, cellulose I, to an activated crystal phase, cellulose IIII, by ammonia treatment. The detailed crystal structures determined for cellulose IΒ, an intermediate ammonia-cellulose I complex, and cellulose IIII, reveal a structural transition pathway: hydrogen bonded sheets of chains in cellulose IΒ slip with respect to each other to accommodate the penetrating ammonia guest molecules in the intermediate complex. On evaporation of ammonia from the intermediate complex, there is a relative small change in chain packing as an inter-sheet ammonia bridge is replaced by an inter-sheet hydrogen bond in cellulose IIII. When cellulose IIII is heated it converts back to cellulose IΒ. Both ammonia-cellulose I and cellulose IIII have extended chains of cooperative hydrogen bonds in relatively open crystal structures that may add to their susceptibility to rapid change.",

keywords = "Cellulose, Fiber, Hydrogen bond, Neutron crystallography, X-ray crystallography",

author = "Masahisa Wada and Yoshiharu Nishiyama and Henri Chanzy and Trevor Forsyth and Paul Langan",

year = "2008",

doi = "10.1154/1.2912442",

language = "English",

volume = "23",

pages = "92--95",

journal = "Powder Diffraction",

issn = "0885-7156",

publisher = "Cambridge University Press",

number = "2",

}

TY - JOUR

T1 - The structure of celluloses

AU - Wada, Masahisa

AU - Nishiyama, Yoshiharu

AU - Chanzy, Henri

AU - Forsyth, Trevor

AU - Langan, Paul

PY - 2008

Y1 - 2008

N2 - X-ray and neutron fiber diffraction has been used to study cellulose as it is converted from its naturally occurring crystal phase, cellulose I, to an activated crystal phase, cellulose IIII, by ammonia treatment. The detailed crystal structures determined for cellulose IΒ, an intermediate ammonia-cellulose I complex, and cellulose IIII, reveal a structural transition pathway: hydrogen bonded sheets of chains in cellulose IΒ slip with respect to each other to accommodate the penetrating ammonia guest molecules in the intermediate complex. On evaporation of ammonia from the intermediate complex, there is a relative small change in chain packing as an inter-sheet ammonia bridge is replaced by an inter-sheet hydrogen bond in cellulose IIII. When cellulose IIII is heated it converts back to cellulose IΒ. Both ammonia-cellulose I and cellulose IIII have extended chains of cooperative hydrogen bonds in relatively open crystal structures that may add to their susceptibility to rapid change.

AB - X-ray and neutron fiber diffraction has been used to study cellulose as it is converted from its naturally occurring crystal phase, cellulose I, to an activated crystal phase, cellulose IIII, by ammonia treatment. The detailed crystal structures determined for cellulose IΒ, an intermediate ammonia-cellulose I complex, and cellulose IIII, reveal a structural transition pathway: hydrogen bonded sheets of chains in cellulose IΒ slip with respect to each other to accommodate the penetrating ammonia guest molecules in the intermediate complex. On evaporation of ammonia from the intermediate complex, there is a relative small change in chain packing as an inter-sheet ammonia bridge is replaced by an inter-sheet hydrogen bond in cellulose IIII. When cellulose IIII is heated it converts back to cellulose IΒ. Both ammonia-cellulose I and cellulose IIII have extended chains of cooperative hydrogen bonds in relatively open crystal structures that may add to their susceptibility to rapid change.

KW - Cellulose

KW - Fiber

KW - Hydrogen bond

KW - Neutron crystallography

KW - X-ray crystallography

UR - https://www.scopus.com/pages/publications/44649193238

U2 - 10.1154/1.2912442

DO - 10.1154/1.2912442

M3 - Article

AN - SCOPUS:44649193238

SN - 0885-7156

VL - 23

SP - 92

EP - 95

JO - Powder Diffraction

JF - Powder Diffraction

IS - 2

ER -

The structure of celluloses

Abstract

Keywords

Access to Document

Other files and links

Fingerprint

Cite this