Hydrophobisation of lignocellulosic materials part I: physical modification

Johansson³

et al. 2022

Cellulose

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Lignocellulosic materials with hydrophobic properties are of great interest for developing sustainable products that can be used in various applications such as packaging, water-repellent and self-cleaning materials, oil and water separation or as reinforcements in biocomposite materials. The hydroxyl functional groups present in cellulose provide the possibility to perform various chemical modifications to the cellulosic substrates that can increase their hydrophobicity. This review is the second part of a comprehensive review on hydrophobization of lignocellulosic materials and summarizes the recent advances in the chemical modification of such substrates. The methods described in this review can provide changes in the hydrophilicity of the materials that range from a small decrease in the initial hydrophilicity of the substrate (contact angles below 90°) to superhydrophobic properties (contact angles above 150°). Additional attention has been paid to whether the modification is limited to the surface of the substrate or if it occurs in the bulk of the material. We also discuss hydrophobized cellulose material applications in packing and oil/water purification. Graphical abstract

Section: The Role Of Hydrophobization In Packagingmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Hydrophobization of lignocellulosic materials part II: chemical modification

Rodríguez-Fabià¹,

Johansson³

et al. 2022

Cellulose

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“…However, other factors, such as the films' porosity, density, or the crystals' alignment, can influence their mechanical properties. The mechanical properties of CNC 10,11 or CNF 12 films can be improved by chemical modification or decreasing crystallinity.Water swelling has a negative impact on cellulosic material applications in packaging 13,14 and as composite additives 15 . It is thus important to investigate such behaviour in neat cellulosic materials, to better be able to tune or reduce water swelling.Studies in this paper were performed with constant water present, and varying temperature.…”

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confidence: 99%

“…Water swelling has a negative impact on cellulosic material applications in packaging 13,14 and as composite additives 15 . It is thus important to investigate such behaviour in neat cellulosic materials, to better be able to tune or reduce water swelling.…”

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confidence: 99%

The influence of temperature on cellulose swelling at constant water density

Ottesen

Rodríguez-Fabià³

et al. 2022

Sci Rep

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We have in this paper investigated how water sorbs to cellulose. We found that both cellulose nanofibril (CNF) and cellulose nanocrystal (CNC) films swell similarly, as they are both mainly composed of cellulose. CNF/CNC films subjected to water at 0.018 kg/m3 at 25 °C and 39 °C, showed a decrease in swelling from ~ 8 to 2%. This deswelling increased the tensile index of CNF-films by ~ 13%. By molecular modeling of fibril swelling, we found that water sorbed to cellulose exhibits a decreased diffusion constant compared to bulk water. We quantified this change and showed that diffusion of sorbed water displays less dependency on swelling temperature compared to bulk water diffusion. To our knowledge, this has not previously been demonstrated by molecular modeling. The difference between bulk water diffusion (DWW) and diffusion of water sorbed to cellulose (DCC) increased from DWW − DCC ~ 3 × 10–5 cm/s2 at 25 °C to DWW − DCC ~ 8.3 × 10–5 cm/s2 at 100 °C. Moreover, water molecules spent less successive time sorbed to a fibril at higher temperatures.

Hydrophobization of lignocellulosic materials part III: modification with polymers

Rodríguez-Fabià¹,

Johansson³

et al. 2022

Cellulose

This review is the third part of a series of reviews on hydrophobization of lignocellulosic materials, a relevant topic nowadays, due to the need to replace fossil fuel-based materials. The review provides an overview of the hydrophobization of lignocellulosic materials by polymer adsorption, and both chemical and radiation-induced grafting of polymers. While adsorbed polymers are only attached to the surfaces by physical interactions, grafted polymers are chemically bonded to the materials. Radiation-induced grafting is typically the most environmentally friendly grafting technique, even though it provides little control on the polymer synthesis. On the other hand, controlled radical polymerization reactions are more complex but allow for the synthesis of polymers with elaborated architectures and well-defined properties. Overall, a wide range of contact angles can be obtained by polymer adsorption and grafting, from a slight increase in hydrophobicity to superhydrophobic properties. The choice of modification technique depends on the end-use of the modified material, but there is a clear trend towards the use of more environmentally friendly chemicals and processes and the grafting of polymers with complex structures. Graphical abstract