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Small angle scattering in the Porod region from hydrated paper sheets at varying humidities

  • Christopher J. Garvey , Ian H. Parker , Robert B. Knott and George P. Simon
Published/Copyright: June 1, 2005
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Holzforschung
From the journal Volume 58 Issue 5

Abstract

The microscopic changes in the structure of paper at different equilibrium moisture contents were examined using the novel technique of contrast variation small angle neutron scattering (SANS). Contrast variation, by appropriate selection of the H2O:D2O ratio, was used to simplify the scattering from hydrated paper to a two-phase approximation. The two phases were paper polymers (cellulose, lignin and hemicelluloses) and a phase consisting of water and voids. The two-phase approximation is justified by consideration of the chemistry and density of each of the polymer species belonging to paper, and by matching the scattering length density of the sorbed moisture to air. The neutron intensity at the higher scattering angles examined was successfully fitted using the Porod law, which is applicable to scattering from a two-phase system at the high scattering angle limit. This limit is related to the specific surface area between the two phases. The limiting scattered intensity of neutrons was found to increase with increasing moisture content for a range of paper materials. It is concluded that the sorption of water increased the limiting intensity because water disrupted polymer-polymer bonding. The Porod law also predicts the slope of the intensity/scattering angle curve at the high scattering angle limit.

Keywords: contrast variation; hydrogen bonding; paper hydration; Porod law; SANS; small angle neutron scattering
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Corresponding author. Australian Nuclear Science and Technology Organisation, PMB 1, Menai NSW 2234, Australia. E-mail:

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Published Online: 2005-06-01
Published in Print: 2004-08-01

© Walter de Gruyter

Articles in the same Issue

  1. The effects of initial spacing on wood density, fibre and pulp properties in jack pine (Pinus banksiana Lamb.)
  2. An improved procedure for isolation of residual lignins from hardwood kraft pulps
  3. Small angle scattering in the Porod region from hydrated paper sheets at varying humidities
  4. Application of confocal Raman spectroscopy for the topochemical distribution of lignin and cellulose in plant cell walls of beech wood (Fagus sylvatica L.) compared to UV microspectrophotometry
  5. UV-microscopic analysis of acetylated spruce and birch cell walls
  6. On-line study of lignin behaviour in dilute alkaline solution by the SEC-UV method
  7. Extracellular diffusion pathway for heartwood substances in Albizia julibrissin Durazz.
  8. New glucosides from Eucalyptus globulus wood, bark and kraft pulps
  9. Nondestructive characterization of wood by monitoring of local elastic anisotropy and dynamic nonlinearity
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  11. Thermal forming of chemically modified wood to make high-performance plastic-like wood composites
  12. Eco-composite from poly(lactic acid) and bamboo fiber
  13. Bamboo fiber (BF)-filled poly(butylenes succinate) bio-composite – Effect of BF-e-MA on the properties and crystallization kinetics
  14. Dimensional changes in Corsican pine (Pinus nigra Arnold) modified with acetic anhydride measured using a helium pycnometer
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https://doi.org/10.1515/HF.2004.071
Keywords for this article
contrast variation; hydrogen bonding; paper hydration; Porod law; SANS; small angle neutron scattering

Articles in the same Issue

  1. The effects of initial spacing on wood density, fibre and pulp properties in jack pine (Pinus banksiana Lamb.)
  2. An improved procedure for isolation of residual lignins from hardwood kraft pulps
  3. Small angle scattering in the Porod region from hydrated paper sheets at varying humidities
  4. Application of confocal Raman spectroscopy for the topochemical distribution of lignin and cellulose in plant cell walls of beech wood (Fagus sylvatica L.) compared to UV microspectrophotometry
  5. UV-microscopic analysis of acetylated spruce and birch cell walls
  6. On-line study of lignin behaviour in dilute alkaline solution by the SEC-UV method
  7. Extracellular diffusion pathway for heartwood substances in Albizia julibrissin Durazz.
  8. New glucosides from Eucalyptus globulus wood, bark and kraft pulps
  9. Nondestructive characterization of wood by monitoring of local elastic anisotropy and dynamic nonlinearity
  10. Chemical reaction of maritime pine sapwood (Pinus pinaster Soland) with alkoxysilane molecules: A study of chemical pathways
  11. Thermal forming of chemically modified wood to make high-performance plastic-like wood composites
  12. Eco-composite from poly(lactic acid) and bamboo fiber
  13. Bamboo fiber (BF)-filled poly(butylenes succinate) bio-composite – Effect of BF-e-MA on the properties and crystallization kinetics
  14. Dimensional changes in Corsican pine (Pinus nigra Arnold) modified with acetic anhydride measured using a helium pycnometer
  15. Microwave-enhanced release of formaldehyde from plywood
  16. Artificial weathering of tropical woods. Part 1: Changes in wettability
  17. Artificial weathering of tropical woods. Part 2: Color change
  18. Inhibition of fungal degradation of wood by 2-hydroxypyridine-N-oxide
  19. Microwave treatment to accelerate fixation of copper-ethanolamine (Cu-EA) treated wood
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