Ionization of Cellobiose in Aqueous Alkali and the Mechanism of Cellulose Dissolution

Bialik, Erik; Stenqvist, Björn; Fang, Yuan; Östlund, Åsa; Furó, István; Lindman, Björn; Lund, Mikael; Bernin, Diana

doi:10.1021/acs.jpclett.6b02346

Cited by 75 publications

(48 citation statements)

References 36 publications

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“…This can be explained by that the OH 2 hydroxyl group is equatorial in Glc, but axial in Man. Similar coordination has been seen previously in simulations of cellobiose, and has been suggested to induce deprotonation of cellulose in alkali solvents systems (Bialik et al 2016;Lindman et al 2017). Furthermore, Glc experienced an even higher coordination of OH -in the Gal substituted oligomer (MGLM), possibly a consequence of that the Glc and Gal groups can coordinate a OH -together as showed in Fig.…”

Section: Discussionsupporting

confidence: 85%

“…The purpose was to investigate if the Gal substitution affected the interaction between OH -and the backbone hydroxyl groups. Previous work on cellobiose has also showed that deprotonation of the hydroxyl group is likely to occur on C2 (Bialik et al 2016). The C2 hydroxyl group is of largest interest since alkaline hydrolysis of the glycosidic linkage has been Fig.…”

Section: Composition and Properties Of Extracted Ggm And Mannan Modelmentioning

confidence: 99%

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The structure of galactoglucomannan impacts the degradation under alkaline conditions

et al. 2018

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Galactoglucomannan (GGM) from spruce was studied with respect to the degradation behavior in alkaline solution. Three reference systems including galactomannan from locust bean gum, glucomannan from konjac and the linear water-soluble carboxymethyl cellulose were studied with focus on molecular weight, sugar composition, degradation products, as well as formed oligomers, to identify relative structural changes in GGM. Initially all mannan polysaccharides showed a fast decrease in the molecular weight, which became stable in the later stage. The degradation of the mannan polysaccharides could be described by a function corresponding to the sum of two first order reactions; one slow that was ascribed to peeling, and one fast that was connected with hydrolysis. The galactose side group was stable under conditions used in this study (150 min, 90°C, 0.5 M NaOH). This could suggest that, apart from the covalent connection to C6 in mannose, the galactose substitutions also interact non-covalently with the backbone to stabilize the structure against degradation. Additionally, the combination of different backbone sugars seems to affect the stability of the polysaccharides. For carboxymethyl cellulose the degradation was linear over time which further suggests that the structure and sugar composition play an important role for the alkaline degradation. Molecular dynamics simulations gave details about the conformational behavior of GGM oligomers in water solution, as well as interaction between the oligomers and hydroxide ions.

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Section: Discussionsupporting

confidence: 85%

Section: Composition and Properties Of Extracted Ggm And Mannan Modelmentioning

confidence: 99%

The structure of galactoglucomannan impacts the degradation under alkaline conditions

et al. 2018

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“…However, in light of the lack of frustration in aqueous systems (Medronho et al 2012), this appears unlikely. An alternative explanation for the presence of charge on the cellulose chains is provided by the recent observation that cellulose is deprotonated in aqueous alkali (Bialik et al 2016), as anticipated by Lindman et al (Medronho and Lindman 2014;Alves et al 2015). Thus, we argue that only the role of the TBA þ cation is similar between the TBAAc/DMSO and TBAH/water solvent system; the primary driving forces for cellulose dissolution are distinct.…”

Section: Discussionmentioning

confidence: 47%

On the dissolution of cellulose in tetrabutylammonium acetate/dimethyl sulfoxide: a frustrated solvent

Idström¹,

Gentile

Gubitosi

et al. 2017

Cellulose

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We have found that the dissolution of cellulose in the binary mixed solvent tetrabutylammonium acetate/dimethyl sulfoxide follows a previously overlooked near-stoichiometric relationship such that one dissolved acetate ion is able to dissolve an amount of cellulose corresponding to about one glucose residue. The structure and dynamics of the resulting cellulose solutions were investigated using small-angle X-ray scattering (SAXS) and nuclear magnetic resonance techniques as well as molecular dynamics simulation. This yielded a detailed picture of the dissolution mechanism in which acetate ions form hydrogen bonds to cellulose and causes a diffuse solvation sheath of bulky tetrabutylammonium counterions to form. In turn, this leads to a steric repulsion that helps to keep the cellulose chains apart. Structural similarities to previously investigated cellulose solutions in aqueous tetrabutylammonium hydroxide were revealed by SAXS measurement. To what extent this corresponds to similarities in dissolution mechanism is discussed.

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“…[97][98][99][100] Recently, more conclusive evidence for ionization at high pH has been obtained by Bialik et al in studies on model systems. 101 To elucidate the dissolution mechanism, these authors performed electrophoretic NMR on cellobiose, a subunit of cellulose, showing that cellobiose acts as an acid with two dissociation steps at pH 12 and 13.5 (Fig. 2, left).…”

Section: Does Cellulose Ionization Contribute To Solubility In Water?mentioning

confidence: 99%

“…However, Bialik et al found that ionization does not depend on whether NaOH or KOH is used to obtain a particular pH. 101 A larger amount of KOH is, however, needed to obtain the same pH because NaOH is a stronger base. Hence, the apparent cation specificity previously reported 102,103 What can we learn from cellulose derivatives?…”

Section: Does Cellulose Ionization Contribute To Solubility In Water?mentioning

confidence: 99%

The relevance of structural features of cellulose and its interactions to dissolution, regeneration, gelation and plasticization phenomena

Lindman

Medronho

Alves

et al. 2017

Phys. Chem. Chem. Phys.

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195

109

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aCellulose is the most abundant polymer and a very important renewable resource. Since cellulose cannot be shaped by melting, a major route for its use for novel materials, new chemical compounds and renewable energy must go via the solution state. Investigations during several decades have led to the identification of several solvents of notably different character. The mechanisms of dissolution in terms of intermolecular interactions have been discussed from early work but, even on fundamental aspects, conflicting and opposite views appear. In view of this, strategies for developing new solvent systems for various applications have remained obscure. There is for example a strong need for using forest products for higher value materials and for environmental and cost reasons to use water-based solvents. Several new water-based solvents have been developed recently but there is no consensus regarding the underlying mechanisms. Here we wish to address the most important mechanisms described in the literature and confront them with experimental observations. A broadened view is helpful for improving the current picture and thus cellulose derivatives and phenomena such as fiber dissolution, swelling, regeneration, plasticization and dispersion are considered. In addition to the matter of hydrogen bonding versus hydrophobic interactions, the role of ionization as well as some applications of new knowledge gained are highlighted.

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Ionization of Cellobiose in Aqueous Alkali and the Mechanism of Cellulose Dissolution

Cited by 75 publications

References 36 publications

The structure of galactoglucomannan impacts the degradation under alkaline conditions

The structure of galactoglucomannan impacts the degradation under alkaline conditions

On the dissolution of cellulose in tetrabutylammonium acetate/dimethyl sulfoxide: a frustrated solvent

The relevance of structural features of cellulose and its interactions to dissolution, regeneration, gelation and plasticization phenomena

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