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Filling the gap : modelling sorption isotherms between hygroscopic and water-saturated conditions based on microscopic characterisation of softwood anatomy

Fredriksson, Maria LU orcid ; Thybring, Emil Engelund LU orcid ; Digaitis, Ramūnas LU and Thygesen, Lisbeth Garbrecht (2025) In Cellulose 32(11). p.6753-6773
Abstract

The relation between moisture content of a material and the ambient climate is described by sorption isotherms. Several models for prediction of sorption isotherms exist in the hygroscopic moisture range, but models of sorption isotherms in the over-hygroscopic range are less abundant. In wood, water can be present both in the solid cell wall and in the macro voids (e.g. cell lumina, pit chambers) in the wood structure. In the over-hygroscopic range, moisture uptake primarily occurs in the porous structure outside of the cell walls by capillary condensation. That is, condensation occurs at a certain partial pressure which depends on pore size and geometry. Since wood has an ordered structure and distinct geometries this link enables... (More)

The relation between moisture content of a material and the ambient climate is described by sorption isotherms. Several models for prediction of sorption isotherms exist in the hygroscopic moisture range, but models of sorption isotherms in the over-hygroscopic range are less abundant. In wood, water can be present both in the solid cell wall and in the macro voids (e.g. cell lumina, pit chambers) in the wood structure. In the over-hygroscopic range, moisture uptake primarily occurs in the porous structure outside of the cell walls by capillary condensation. That is, condensation occurs at a certain partial pressure which depends on pore size and geometry. Since wood has an ordered structure and distinct geometries this link enables prediction of the relative humidity at which capillary condensation occurs in different macro voids. Here, this was explored by using a mathematical model for prediction of moisture sorption by capillary condensation in the macro void structures of softwoods. Both absorption and desorption isotherms were modelled, and sorption hysteresis was included by the ink-bottle effect. The model was based on wood anatomy data which was determined for softwood material based on quantitative wood anatomy. The modelling results were compared to experimental sorption data. In general, there was a reasonable agreement; two different theoretical criteria for emptying of cell lumina in desorption were tested and, in most cases, the experimental data were in between these two versions of the modelled desorption isotherms. The moisture content at saturation was, however, most often underestimated by the model.

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author
; ; and
organization
publishing date
type
Contribution to journal
publication status
published
subject
keywords
Capillary condensation, Microscopy, Modelling, Moisture, Over-hygroscopic range, Porosity, Pressure plate, Sorption, Sorption hysteresis, Sorption isotherm, Wood
in
Cellulose
volume
32
issue
11
pages
21 pages
publisher
Springer
external identifiers
  • scopus:105008816544
ISSN
0969-0239
DOI
10.1007/s10570-025-06626-4
language
English
LU publication?
yes
id
45ccbdb8-99d0-4e08-abd0-a04d54c14995
date added to LUP
2025-12-12 12:56:15
date last changed
2025-12-12 12:56:55
@article{45ccbdb8-99d0-4e08-abd0-a04d54c14995,
  abstract     = {{<p>The relation between moisture content of a material and the ambient climate is described by sorption isotherms. Several models for prediction of sorption isotherms exist in the hygroscopic moisture range, but models of sorption isotherms in the over-hygroscopic range are less abundant. In wood, water can be present both in the solid cell wall and in the macro voids (e.g. cell lumina, pit chambers) in the wood structure. In the over-hygroscopic range, moisture uptake primarily occurs in the porous structure outside of the cell walls by capillary condensation. That is, condensation occurs at a certain partial pressure which depends on pore size and geometry. Since wood has an ordered structure and distinct geometries this link enables prediction of the relative humidity at which capillary condensation occurs in different macro voids. Here, this was explored by using a mathematical model for prediction of moisture sorption by capillary condensation in the macro void structures of softwoods. Both absorption and desorption isotherms were modelled, and sorption hysteresis was included by the ink-bottle effect. The model was based on wood anatomy data which was determined for softwood material based on quantitative wood anatomy. The modelling results were compared to experimental sorption data. In general, there was a reasonable agreement; two different theoretical criteria for emptying of cell lumina in desorption were tested and, in most cases, the experimental data were in between these two versions of the modelled desorption isotherms. The moisture content at saturation was, however, most often underestimated by the model.</p>}},
  author       = {{Fredriksson, Maria and Thybring, Emil Engelund and Digaitis, Ramūnas and Thygesen, Lisbeth Garbrecht}},
  issn         = {{0969-0239}},
  keywords     = {{Capillary condensation; Microscopy; Modelling; Moisture; Over-hygroscopic range; Porosity; Pressure plate; Sorption; Sorption hysteresis; Sorption isotherm; Wood}},
  language     = {{eng}},
  number       = {{11}},
  pages        = {{6753--6773}},
  publisher    = {{Springer}},
  series       = {{Cellulose}},
  title        = {{Filling the gap : modelling sorption isotherms between hygroscopic and water-saturated conditions based on microscopic characterisation of softwood anatomy}},
  url          = {{http://dx.doi.org/10.1007/s10570-025-06626-4}},
  doi          = {{10.1007/s10570-025-06626-4}},
  volume       = {{32}},
  year         = {{2025}},
}