water vapour sorption properties of Sitka spruce determined using a dynamic vapour sorption apparatus

The water vapour sorption properties of Sitka spruce (Picea abies) have been investigated over a range of temperatures (14.2-43.8°C) using a dynamic vapour sorption apparatus. The sorption kinetics behaviour was evaluated using the parallel exponential kinetics model which has been found to give ver...

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Bibliographic Details
Published in:Wood science and technology 2010-08, Vol.44 (3), p.497-514
Main Authors: Hill, Callum A. S, Norton, Andrew J, Newman, Gary
Format: Article
Language:English
Subjects:
Adsorption
Biomedical and Life Sciences
Ceramics
Composites
Desorption
Fibers
Food plants
Glass
Glass transition temperature
Hysteresis loops
Isotherms
Kinetics
Life Sciences
Machines
Manufacturing
Natural Materials
Original
Picea sitchensis
Processes
Relative humidity
Sorption
Temperature
Temperature dependence
Temperature effects
Transition temperatures
Vapors
Vegetable fibers
Water vapor
Wetting
Wood Science & Technology
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Summary:The water vapour sorption properties of Sitka spruce (Picea abies) have been investigated over a range of temperatures (14.2-43.8°C) using a dynamic vapour sorption apparatus. The sorption kinetics behaviour was evaluated using the parallel exponential kinetics model which has been found to give very accurate fits to the data in studies of foodstuffs or plant fibres, but has not been previously applied to sorption studies with wood. Both the adsorption and desorption kinetics curve can be deconvoluted into a fast and slow exponential process. Under conditions of adsorption, the fast process appears to be associated with the formation of monolayer water (determined using the Hailwood Horrobin model) up to a relative humidity of 20%. Under desorption, there is no clear differentiation between fast and slow processes. The area bounded by the sorption hysteresis loop reduced as the temperature at which the isotherm was measured increased, due to movement of the desorption curve only, with the adsorption curve remaining the same at all temperatures. This behaviour is consistent with sorption processes taking place on nanoporous glassy solids below the glass transition temperature. The heat of wetting was determined from the temperature dependence of the desorption isotherms by using the Clausius-Clapeyron equation, yielding results that are consistent with literature values. However, doubts are raised in this paper as to the applicability of using the Clausius-Clapeyron equation for analyses of this type.
ISSN:0043-7719
1432-5225
DOI:10.1007/s00226-010-0305-y