Production of Furfural from Process-Relevant Biomass-Derived Pentoses in a Biphasic Reaction System

Mittal, Ashutosh; Black, Stuart; Vinzant, Todd B.; O’Brien, Marykate H.; Tucker, Melvin P.; Johnson, David K.

doi:10.1021/acssuschemeng.7b00215

Cited by 149 publications

(100 citation statements)

References 31 publications

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“…Furfural can be produced from xylose by acid dehydration, which in turn can be obtained from hemicelluloses, one of the three main fractions of lignocellulosic biomass . Furfural can also be produced from xylans and whole biomass . The first industrial furfural production process dates back to 1921, with the Quaker Oats batch process using oat hulls .…”

Section: Introductionsupporting

confidence: 85%

Enhanced Conversion of Xylan into Furfural using Acidic Deep Eutectic Solvents with Dual Solvent and Catalyst Behavior

Morais

Freire

et al. 2020

ChemSusChem

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An efficient process for the production of furfural from xylan by using acidic deep eutectic solvents (DESs), which act both as solvents and catalysts, is developed. DESs composed of cholinium chloride ([Ch]Cl) and malic acid or glycolic acid at different molar ratios, and the effects of water and γ‐valerolactone (GVL) contents, solid/liquid (S/L) ratio, and microwave heating are investigated. The best furfural yields are obtained with the DES [Ch]Cl:malic acid (1:3 molar ratio)+5 wt % water, under microwave heating for 2.5 min at 150 °C, a S/L ratio of 0.050, and GVL at a weight ratio of 2:1. Under these conditions, a remarkable furfural yield (75 %) is obtained. Direct distillation of furfural from the DES/GVL solvent and distillation from 2‐methyltetrahydrofuran (2‐MeTHF) after a back‐extraction step enable 89 % furfural recovery from 2‐MeTHF. This strategy allows recycling of the DES/GVL for at least three times with only small losses in furfural yield (>69 %). This is the fastest and highest‐yielding process reported for furfural production using bio‐based DESs as solvents and catalysts, paving the way for scale‐up of the process.

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Section: Introductionsupporting

confidence: 85%

Enhanced Conversion of Xylan into Furfural using Acidic Deep Eutectic Solvents with Dual Solvent and Catalyst Behavior

Morais

Freire

et al. 2020

ChemSusChem

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“…Therefore, FUR would be protected in the organic solvent and hence avoid losses by humin formation, and FUR yield would be improved . Several publications have reported the addition of methyl isobutyl ketone (MIBK), 2‐methyltetrahydrofuran (MTHF), toluene, cyclohexanol, tetrahydrofuran (THF), dimethyl sulfoxide (DMSO),,, cyclopentyl methyl ether (CPME),, and the widely used toluene,, as efficient co‐solvents for the formation of FUR from xylose. IL have also been used to back up hemicellulose depolymerization .…”

Section: Catalytic Production Of Platform Chemicals From Lignocellulomentioning

confidence: 99%

Recent Advances in the Catalytic Production of Platform Chemicals from Holocellulosic Biomass

et al. 2019

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This Review discusses novel catalytic pathways of lignocellulosic biomass to value‐added chemicals including biomass‐derived sugar alcohols, organic acids, furans and biohydrocarbons. These production approaches are undertaken by biological, chemical and thermochemical transformations or a combination of them. Nevertheless, the majority of research in this area is focused on the design of heterogeneous catalysts to convert value‐added products from holocellulosic biomass. Biorefineries represent the peak of biomass processes in order to produce valuable chemicals and liquid fuels avoiding the utilization of corroding and toxic elements. The aim of the present Review is to offer the readers a broad overview of recent holocellulosic‐based chemical and fuels production technologies via heterogeneous catalysis. There is also an overview of the economic aspects to efficiently produce these platform chemicals at industrial scale. To summarize this Review, an outlook and conclusions of the reported processes to date is provided.

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“…By contrast, furfural yields from steam-exploded bagasse were stoichiometric for both catalytic systems, therefore revealing the beneficial effect of pretreatment on hemicellulose conversion, which includes deacetylation, partial hydrolysis and swelling from their tight association with cellulose and lignin in the original material. [4][5][6][7] In terms of mass yields, α-cellulose was the cellulosic matrix that produced more furan compounds, which corresponded to 33.1% for ZnCl 2 /HCl and 38.3% for AlCl 3 /HCl (Figure 4). These higher mass yields were related to the low crystallinity and absence of lignin in this cellulosic material.…”

Section: Resultsmentioning

confidence: 99%

“…One of the most interesting pretreatment technique is steam explosion, which combines chemical and physical processes to deconstruct the plant cell wall associative structure. 5,6 For this, the biomass is treated with saturated steam at temperatures between 170-230 °C for 2 to 30 min in the absence or presence of an exogenous catalyst. 7 The main feature of steam explosion is the total or partial acid hydrolysis of hemicelluloses to produce mono and oligosaccharides, which are intermediate chemicals for a variety of value-added products.…”

Section: 2mentioning

confidence: 99%

“…5,[14][15][16] These systems avoid the main side-reactions in dehydration, such as rehydration to produce levulinic and formic acids and condensation of furan derivatives to produce a dark insoluble solid residue called humins. 17,18 The best choice for the production of furan compounds is the use of a biphasic system that is formed by an aqueous phase (reaction solvent) and an organic phase (extraction solvent).…”

mentioning

confidence: 99%

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Production of Furan Compounds from Sugarcane Bagasse Using a Catalytic System Containing ZnCl2/HCl or AlCl3/HCl in a Biphasic System

Gomes¹,

Rampon²,

Ramos³

2018

J. Braz. Chem. Soc.

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In this work, two catalytic systems combining Lewis and Brønsted acids (ZnCl 2 /HCl and AlCl 3 /HCl) were applied in a tetrahydrofuran (THF)/NaCl aq biphasic system to produce furan compounds from plant polysaccharides. The following cellulosic matrices were applied for this purpose: α-cellulose, microcrystalline cellulose and both native and steam-exploded sugarcane bagasse. The AlCl 3 /HCl catalytic system afforded the best yields for α-cellulose conversion to furan compounds (hydrolysis followed by dehydration). The highest yields of 5-(hydroxymethyl)-furfural (HMF) and furfural were 44.0 and 92.2% for AlCl 3 /HCl and 36.5 and 81.4% for ZnCl 2 /HCl, respectively. Cellulosic materials with lower crystallinity indexes afforded the best performance in hydrolysis followed by dehydration, giving relatively high yields of HMF and furfural. The HMF yields were similar for both native and steam-exploded sugarcane bagasse and the presence of lignin had a negative effect on HMF production. The highest furfural yield from native sugarcane bagasse was 60.6% with AlCl 3 /HCl catalytic system. Keywords: acid-catalyzed dehydration, furans, cellulose, sugarcane bagasse, crystallinity IntroductionThe integral use of renewable feedstocks for fuels and chemicals is the key for the development of sustainable biorefineries. The International Energy Agency (IEA) defines biorefinery as the sustainable processing of biomass into a spectrum of products to be marketed as food, chemicals and supplies. In another definition, the American National Renewable Energy Laboratory (NREL) describes biorefinery as a facility that integrates equipment and processes for biomass conversion into fuels, energy and chemicals for industry. 1,2Sugarcane bagasse is an important agro-industrial byproduct for biorefining because large amounts are readily available at low cost in sugarcane-processing industrial facilities such as autonomous distilleries and sugar mills. Sugarcane bagasse is majorly composed of glucans (mostly cellulose), hemicelluloses (mostly xylans) and lignin and these macromolecular components are involved in a strong chemical association that reduces its accessibility to chemical conversion. 4 Different forms of pretreatment can break this strong association and increase the chemical accessibility of cane bagasse polysaccharides. One of the most interesting pretreatment technique is steam explosion, which combines chemical and physical processes to deconstruct the plant cell wall associative structure. 5,6 For this, the biomass is treated with saturated steam at temperatures between 170-230 °C for 2 to 30 min in the absence or presence of an exogenous catalyst. 7 The main feature of steam explosion is the total or partial acid hydrolysis of hemicelluloses to produce mono and oligosaccharides, which are intermediate chemicals for a variety of value-added products. In addition, changes in the lignin structure occur primarily due to the acid hydrolysis of aril-ether linkages, while both xylan and glucan degree of polymerization is decreas...

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Production of Furfural from Process-Relevant Biomass-Derived Pentoses in a Biphasic Reaction System

Cited by 149 publications

References 31 publications

Enhanced Conversion of Xylan into Furfural using Acidic Deep Eutectic Solvents with Dual Solvent and Catalyst Behavior

Enhanced Conversion of Xylan into Furfural using Acidic Deep Eutectic Solvents with Dual Solvent and Catalyst Behavior

Recent Advances in the Catalytic Production of Platform Chemicals from Holocellulosic Biomass

Production of Furan Compounds from Sugarcane Bagasse Using a Catalytic System Containing ZnCl2/HCl or AlCl3/HCl in a Biphasic System

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