Inkjet printing inks commonly contain low volatility and polar liquids, such as glycerol or poly(ethylene glycols), along with water as the main solvent. The deposition of these liquids on paper leads to swelling and anisotropic deformation of the cellulose fibers. The dynamics of expansion provide insights into the distribution of co-solvents within the fibers, with the timescales of pore-fiber transport depending on the co-solvent concentration.
Inkjet printing inks frequently contain polar liquids of low volatility such as glycerol or poly(ethylene glycols) in addition to the main solvent water. The deposition of these liquids on paper sheets induces swelling of the cellulose fibers, which leads to an overall, anisotropic deformation of the sheet. We characterized the corresponding strain components by means of a grid projection method and white light interferometry. For pure water, most of the hydroexpansion strain vanishes again after drying is complete. However, for aqueous solutions of non-volatile co-solvents, a large fraction of the deformation persists after the water has evaporated. Because swelling occurs only after liquid enters the cellulose fibers, monitoring the dynamics of expansion provides insight into the pore-fiber distribution of co-solvents. The corresponding timescales of pore-fiber transport strongly depend on the co-solvent concentration, as a sufficient quantity of water is needed to plasticize the fiber walls.
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