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Abstract
To characterise the sorption behaviour of wood or other hygroscopic materials with the use of water vapour sorption experiments, an accurate understanding of water vapour transport both to and through the sample material is necessary. Within the last decades, various modelling approaches on the sorption kinetics were developed, but there seems to be no general agreement on the relevance of water vapour transport. Using small amounts of grained wood, this study aims to estimate the influence of water vapour transport in sorption experiments on small sample sizes. A theoretical analysis based on a diffusion equation including a simplified sink/source term was carried out and compared with corresponding experiments. Nonlinear isotherm and temperature were shown to have a major impact on the effective diffusion of water vapour, whereas step size in humidity seems to mainly influence processes within the cell wall (e.g. relaxation and reorganisation of microstructure). Considering the paths of stagnant air above sample surface, the anomalous behaviour for a variation in sample thickness of grained wood can be explained. In conclusion, water vapour transport appreciably influences the sorption kinetics of small sample sizes and has to be considered in the modelling and interpretation of water vapour sorption experiments.
Highlights
Water vapour sorption (WVS) experiments can be used to characterise the sorption behaviour of water vapour in wood
To assess the importance of water vapour transport (WVT) in WVS experiments on small wooden samples, this study addresses the apparent gap in the literature of a separate investigation on the impact of a nonlinear sink, step size in relative humidity, temperature, moistening method and the paths of stagnant air above sample surface on the WVT during a step change in RH
Water vapour transport has a significant effect on the sorption kinetics of wood and has to be considered even for small sample sizes
Summary
Water vapour sorption (WVS) experiments can be used to characterise the sorption behaviour of water vapour in wood. In addition to sorption isotherms (i.e. equilibrium values), sorption kinetics (i.e. time-dependent mass change) can provide further information on the sorption process and on material behaviour (e.g. Wadsö 1993b; Hill et al 2011b). A. Murr face and through the sample material is involved in experimentally obtained sorption kinetics, it is difficult to separate and identify processes that are taking place within the cell wall of wood (e.g. transport or relaxation and reorganisation of microstructure). Avramidis and Siau 1987; Wadsö 1994b) or differences in the diffusion coefficient between steady-state and transient sorption experiments (e.g. Wadsö 1994a and references therein) were frequently reported for wood and other polymers. In identifying the processes that take place within the cell wall of wood, a proper understanding of WVT is essential. The relevance of WVT on the sorption kinetics of such samples appears to still be undetermined (Himmel and Mai 2016)
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