Recrystallization and size distribution of dislocated segments in cellulose microfibrils—a molecular dynamics perspective

Khodayari, Ali; Hirn, Ulrich; Spirk, Stefan; Vuure, Aart Willem Van; Seveno, David

doi:10.1007/s10570-021-03906-7

Cited by 24 publications

(13 citation statements)

References 45 publications

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“…Similar minor differences due to HCl gas or vapor hydrolysis have been detected in previous X-ray diffraction experiments, 16 , 18 and, for instance—the decrease of the 200 lattice spacing agrees with simulations of recrystallizing cellulose chains after cleavage. 19 Most importantly, however, the crystallinity index increased clearly (by 10–20%), which is a common result obtained for various cellulosic substrates subjected to HCl gas or vapor hydrolysis. 16 − 18 In the current case, it can be assigned to the removal of noncrystalline material and the small increase in crystallite dimensions.…”

Section: Resultsmentioning

confidence: 69%

“…Especially, studies on filter paper, 16 bacterial cellulose, 17 and hardwood cellulose nanofibers 18 have reported increases in cellulose crystallinity with minimal effects on the crystallite dimensions. This effect has been explained by the crystallization of cleaved cellulose chains either in the small disordered domains along the microfibrils 19 or on the hydrophilic surfaces of the cellulose crystals, 20 but the results are not fully consistent. In another work, the HCl vapor hydrolysis of cotton filter papers was found to decrease the water-holding capacity of the cell walls, which was at least partly related to tighter aggregation of cellulose microfibrils in the hydrolyzed samples.…”

Section: Introductionmentioning

confidence: 95%

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Effect of Moisture on Polymer Deconstruction in HCl Gas Hydrolysis of Wood

et al. 2022

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The HCl gas system previously used to produce cellulose nanocrystals was applied on Scots pine wood, aiming at a controlled deconstruction of its macrostructure while understanding the effect on its microstructure. The HCl gas treatments resulted in a well-preserved cellular structure of the wood. Differences in wood initial moisture content (iMC) prior to HCl gas treatment played a key role in hydrolysis rather than the studied range of exposure time to the acidic gas. Higher iMCs were correlated with a higher degradation of hemicellulose, while crystalline cellulose microfibrils were not largely affected by the treatments. Remarkably, the hydrogen–deuterium exchange technique showed an increase in accessible OH group concentration at higher iMCs, despite the additional loss in hemicelluloses. Unrelated to changes in the accessible OH group concentration, the HCl gas treatment reduced the concentration of absorbed D 2 O molecules.

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Section: Resultsmentioning

confidence: 69%

Section: Introductionmentioning

confidence: 95%

Effect of Moisture on Polymer Deconstruction in HCl Gas Hydrolysis of Wood

et al. 2022

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“…Note that degree of crystallinity of cellulose can be quantified by the Ramachandran plot showing the distribution of the main dihedral angles about their glycosidic linkage (Khodayari et al 2021;French et al 2021). We calculated these distributions for the crystalline and amorphous cellulose for both TEMPOand CM-modified cellulose, see Figure S2.…”

Section: Computational Modelmentioning

confidence: 99%

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

Garg

Apostolopoulou‐Kalkavoura

Linares

et al. 2021

Cellulose

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Foams made from cellulose nanomaterials are highly porous and possess excellent mechanical and thermal insulation properties. However, the moisture uptake and hygroscopic properties of these materials need to be better understood for their use in biomedical and bioelectronics applications, in humidity sensing and thermal insulation. In this work, we present a combination of hybrid Grand Canonical Monte Carlo and Molecular Dynamics simulations and experimental measurements to investigate the moisture uptake within nanocellulose foams. To explore the effect of surface modification on moisture uptake we used two types of celluloses, namely TEMPO-oxidized cellulose nanofibrils and carboxymethylated cellulose nanofibrils. We find that the moisture uptake in both the cellulose nanomaterials increases with increasing relative humidity (RH) and decreases with increasing temperature, which is explained using the basic thermodynamic principles. The measured and calculated moisture uptake in amorphous cellulose (for a given RH or temperature) is higher as compared to crystalline cellulose with TEMPO- and CM-modified surfaces. The high water uptake of amorphous cellulose films is related to the formation of water-filled pores with increasing RH. The microscopic insight of water uptake in nanocellulose provided in this study can assist the design and fabrication of high-performance cellulose materials with improved properties for thermal insulation in humid climates or packaging of water sensitive goods. Graphic abstract

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“…At the nanoscale, CNFs are recognized as being highly crystalline with small segments of non-crystalline regions in the longitudinal direction. These areas were formerly called ″amorphous regions″ but modern accounts strongly suggest that they are too short to be consisting of bulky, amorphous cellulose as their length is allegedly somewhere between 1 and 5 nm. , Unlike the completely disordered cellulose polymer chains, which are more accessible to water molecules, the disordered segments do not likely contribute much to the water uptake of CNFs but they are more susceptible to certain chemical reactions, notably acid hydrolysis . The crystalline phase of CNFs is on the other hand the most compacted crystalline building blocks with practically no access to water infiltration and is also resistant to hydrolysis .…”

Section: Introductionmentioning

confidence: 99%

The Impact of Surface Charges of Carboxylated Cellulose Nanofibrils on the Water Motions in Hydrated Films

Guccini

Meng

et al. 2022

Biomacromolecules

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Cellulose nanofibrils (CNFs) with carboxylated surface ligands are a class of materials with tunable surface functionality, good mechanical properties, and bio-/environmental friendliness. They have been used in many applications as scaffold, reinforcing, or functional materials, where the interaction between adsorbed moisture and the CNF could lead to different properties and structures and become critical to the performance of the materials. In this work, we exploited multiple experimental methods to study the water movement in hydrated films made of carboxylated CNFs prepared by TEMPO oxidation with two different surface charges of 600 and 1550 μmol·g –1 . A combination of quartz crystal microbalance with dissipation (QCM-D) and small-angle X-ray scattering (SAXS) shows that both the surface charge of a single fibril and the films’ network structure contribute to the moisture uptake. The films with 1550 μmol·g –1 surface charges take up twice the amount of moisture per unit mass, leading to the formation of nanostructures with an average radius of gyration of 2.1 nm. Via the nondestructive quasi-elastic neutron scattering (QENS), a faster motion is explained as a localized movement of water molecules inside confined spheres, and a slow diffusive motion is found with the diffusion coefficient close to bulk water at room temperature via a random jump diffusion model and regardless of the surface charge in films made from CNFs.

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Recrystallization and size distribution of dislocated segments in cellulose microfibrils—a molecular dynamics perspective

Cited by 24 publications

References 45 publications

Effect of Moisture on Polymer Deconstruction in HCl Gas Hydrolysis of Wood

Effect of Moisture on Polymer Deconstruction in HCl Gas Hydrolysis of Wood

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

The Impact of Surface Charges of Carboxylated Cellulose Nanofibrils on the Water Motions in Hydrated Films

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