Moisture uptake in nanocellulose: the effects of relative humidity, temperature and degree of crystallinity

[1] Aguirre-Loredo RY(2017)Modelling the effect of temperature on the water sorption isotherms of chitosan films Food Sci Technol 37 112-118

[2] Rodriguez-Hernandez AI(2019)Ultra-porous nanocellulose foams: a facile and scalable fabrication approach Nanomaterials 9 1-14

[3] Velazquez G(2018)Thermal conductivity of hygroscopic foams based on cellulose nanofibrils and a nonionic polyoxamer Cellulose 25 1117-1126

[4] Antonini C(2021)Humidity-dependent thermal boundary conductance controls heat transport of super-insulating nanofibrillar foams humidity-dependent thermal boundary conductance controls heat transport of super-insulating nanofibrillar foams Matter 4 1-14

[5] Wu T(2011)Water sorption behavior and gas barrier properties of cellulose whiskers and microfibrils films Carbohydr Polym 14 4497-4506

[6] Zimmermann T(2013)Humidity and multiscale structure govern mechanical properties and deformation modes in films of native cellulose nanofibrils Biomacromol 5 16003-16024

[7] Apostolopoulou-Kalkavoura V(2017)Cellulose nanofibril nanopapers and bioinspired nanocomposites: a review to understand the mechanical property space J Mater Chem A 152 679-686

[8] Gordeyeva K(1994)Types of adsorbed water in relation to the ionic groups and their counter-ions for some cellulose derivatives Polymer (guildf) 12 24505-24511

[9] Lavoine N(2016)Synthesis of cellulose acetate and carboxymethylcellulose from sugarcane straw Carbohydr Polym 6 850-861

[10] Bergström L(2020)Light- and humidity-responsive chiral nematic photonic crystal films based on cellulose nanocrystals ACS Appl Mater Interfaces 6 7764-7779

[1] Aguirre-Loredo RY(2017)Modelling the effect of temperature on the water sorption isotherms of chitosan films Food Sci Technol 37 112-118

[2] Rodriguez-Hernandez AI(2019)Ultra-porous nanocellulose foams: a facile and scalable fabrication approach Nanomaterials 9 1-14

[3] Velazquez G(2018)Thermal conductivity of hygroscopic foams based on cellulose nanofibrils and a nonionic polyoxamer Cellulose 25 1117-1126

[4] Antonini C(2021)Humidity-dependent thermal boundary conductance controls heat transport of super-insulating nanofibrillar foams humidity-dependent thermal boundary conductance controls heat transport of super-insulating nanofibrillar foams Matter 4 1-14

[5] Wu T(2011)Water sorption behavior and gas barrier properties of cellulose whiskers and microfibrils films Carbohydr Polym 14 4497-4506

[6] Zimmermann T(2013)Humidity and multiscale structure govern mechanical properties and deformation modes in films of native cellulose nanofibrils Biomacromol 5 16003-16024

[7] Apostolopoulou-Kalkavoura V(2017)Cellulose nanofibril nanopapers and bioinspired nanocomposites: a review to understand the mechanical property space J Mater Chem A 152 679-686

[8] Gordeyeva K(1994)Types of adsorbed water in relation to the ionic groups and their counter-ions for some cellulose derivatives Polymer (guildf) 12 24505-24511

[9] Lavoine N(2016)Synthesis of cellulose acetate and carboxymethylcellulose from sugarcane straw Carbohydr Polym 6 850-861

[10] Bergström L(2020)Light- and humidity-responsive chiral nematic photonic crystal films based on cellulose nanocrystals ACS Appl Mater Interfaces 6 7764-7779