Review of Cellulose Non-Derivatizing Solvent Interactions with Emphasis on Activity in Inorganic Molten Salt Hydrates

Sen, Sanghamitra; Martin, James D.; Argyropoulos, Dimitris S.

doi:10.1021/sc400085a

Cited by 249 publications

(170 citation statements)

References 119 publications

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“…In a perfect molten salt hydrate, all water molecules are tightly bound to the inner coordination sphere of the cation, leaving the anion naked in the system. 40 and able to interact with the O of cellulose hydroxyl groups when dissociated from the coordinated water molecules by heating and, in particular, when part of the water in the system is consumed for hydrolysis of cellulose and hemicelluloses. The cellulose-Br À and cellulose-Li + associations or interactions disrupt the inter-and intra-molecular hydrogen bonding of cellulose, thereby breaking the tight crystalline matrix of cellulose, thus leading to the swelling and dissolution of cellulose.…”

Section: Description Of the Proposed Biphasic Systemmentioning

confidence: 99%

Effective conversion of biomass into bromomethylfurfural, furfural, and depolymerized lignin in lithium bromide molten salt hydrate of a biphasic system

2017

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A novel approach using a biphasic system consisting of a molten lithium bromide hydrate solution (LiBr$3H 2 O) and an organic solvent was developed to efficiently produce furan-based chemicals from cellulose and lignocellulosic biomass. At 125 C for 2 h, the yield of bromomethylfurfural (BMF) from cellulose reached >90% (molar yield), and the yields of furfural (FF) and BMF from real biomass (herbage, hardwood, and softwood) were $70% and $85%, respectively. The reaction mechanisms of the polysaccharides and lignin and the role of the molten salt hydrate were investigated and elucidated. In the biphasic system, hemicelluloses and cellulose of the biomass were dissolved, hydrolyzed, dehydrated and brominated to FF and BMF, respectively, in the aqueous phase, and the furan products were simultaneously extracted into and cumulated in the organic phase. Meanwhile, lignin in the biomass was significantly depolymerized through the cleavage of b-aryl ether linkages and separated with high purity for potential coproducts.

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Section: Description Of the Proposed Biphasic Systemmentioning

confidence: 99%

Effective conversion of biomass into bromomethylfurfural, furfural, and depolymerized lignin in lithium bromide molten salt hydrate of a biphasic system

2017

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“…In fact, except for direct application in its natural fiber form, cellulose cannot melt, it should be processed via dissolution or derivatization. Several solvents were studied to dissolve cellulose showing several cellulose-solvent interaction mechanisms (Sen et al 2013). Nuclear magnetic resonance (NMR) is one of the most suitable techniques to study cellulose dissolution and aggregation (Isogai 1997;Kamide et al 1985;VanderHart and Atalla 1984).…”

Section: Introductionmentioning

confidence: 99%

Cellulose–solvent interactions from self-diffusion NMR

Gentile

Olsson

2016

Cellulose

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Molecular self-diffusion coefficients were measured in solutions of microcrystalline cellulose (MCC) and dissolving pulp, in 40 wt% aqueous tetrabutylammonium hydroxide (TBAH), using pulsed field gradient stimulated echo NMR. From the cellulose diffusion coefficients, a weight averaged radius of hydration \R h [ w = 6.1 nm for MCC and \R h [ w = 15 nm for pulp were obtained. Water and TBA ? ions show a significantly different dependence on the cellulose concentration, revealing different molecular interactions with the polymer. Watercellulose are essentially excluded volume. TBA ? ions, on the other hand, bind to cellulose with approximately 1.2 TBA ? ions per glucose unit.

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“…In addition, cationized cellulose, produced by homogeneous cationization with 2,3-epoxypropyltrimethylammonium chloride (EPTMAC), was reported to exhibit good cationic flocculation ability toward kaolin suspensions [25]. However, as cellulose is highly crystallized by a strong network of inter-and intra-molecular hydrogen bonds, its dissolution requires a time-consuming processing with unpopular solvents such as aqueous sodium hydroxide/urea solution, lithium chloride/dimethyl sulfoxide, tetra-n-butylammonium fluoride/dimethyl sulfoxide, and specific ionic liquids, and/or preswelling by sequential solvent change and heating [26]. In our previous work, cellulose ampholytes (CAms) containing both cationic quaternary ammonium sodium salt and anionic carboxymethyl groups were prepared from homogeneous etherification of CMC dissolved in aqueous solution in the presence of EPTMAC as cationic reagent.…”

Section: Introductionmentioning

confidence: 99%

Removal of anionic dyes in aqueous solution by flocculation with cellulose ampholytes

Kono

Kusumoto

2015

Journal of Water Process Engineering

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a b s t r a c tCellulose ampholytes (CAms) prepared from biocompatible and biodegradable carboxymethyl cellulose (CMC) could represent an environmentally friendly alternative for the efficient removal of anionic dyes from water effluents. In order to evaluate their potential for this application, a series of CAms with a degree of cationic substitution (DS C ) between 0.26 and 1.08 were prepared from sodium CMC, by cationization with 2,3-epoxypropyltrimethylammonium chloride. The flocculation ability of the CAms against the anionic dye Acid Red 13 (AR13) was found to strongly depend on the DS C as well as on the pH of the solution. The highest flocculation ability was observed at lower pH and higher DS C : a color removal as high as 99% was achieved at pH 3 using a CAm with the highest DS C . The kinetic analysis revealed that the flocculation of AR13 can be accurately fitted by a pseudo-second order kinetic model, which thus allows to predict the flocculation behavior of CAms under these conditions. Besides AR13, the ampholytes also showed high flocculation ability against Acid Red 9 and Acid Blue 13. The flocculation behavior of these anionic dyes followed the Langmuir adsorption isotherm model, which revealed the maximum flocculation capacity of a CAm for these dyes. Moreover, the analysis of the flocculation isotherm data and the SEM observation of the formed flocs allowed to determine the flocculation mechanism.

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Review of Cellulose Non-Derivatizing Solvent Interactions with Emphasis on Activity in Inorganic Molten Salt Hydrates

Cited by 249 publications

References 119 publications

Effective conversion of biomass into bromomethylfurfural, furfural, and depolymerized lignin in lithium bromide molten salt hydrate of a biphasic system

Effective conversion of biomass into bromomethylfurfural, furfural, and depolymerized lignin in lithium bromide molten salt hydrate of a biphasic system

Cellulose–solvent interactions from self-diffusion NMR

Removal of anionic dyes in aqueous solution by flocculation with cellulose ampholytes

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