Effect of aluminium sulphate-catalysed hydrolysis process on furfural yield and cellulose degradation of Cannabis sativa L. shives

Brazdausks, Prans; Pāže, Aigars; Rizhikovs, Janis; Puķe, Māris; Meile, Kristine; Vederņikovs, Nikolajs; Tupčiauskas, Ramūnas; Andžs, Mārtiņš

doi:10.1016/j.biombioe.2016.01.016

Cited by 30 publications

(21 citation statements)

References 29 publications

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“…With longer pretreatment time course, the resulting furfural could not be removed immediately from the reactor, which caused several side reactions to occur. These included the decomposition of furfural into formic acid and the condensations of furfural with furfural, xylose, and lignin-related phenolic compounds (Brazdausks et al 2016). The key to avoiding these side reactions and controlling the furfural recovery and furfural loss was to shorten the residence time of furfural in the aqueous phase (Mao et al 2012).…”

Section: Impact Of Sulfuric Acidmentioning

confidence: 99%

“…Though the catalyst enhances the reaction rate, the rate of side reactions is also enhanced (Jing and Lu 2007). These included the decomposition of furfural into formic acid and the condensations of furfural with furfural, xylose, and lignin-related phenolic compounds (Brazdausks et al 2016). Over the past decade, studies have been conducted on developing a more economical and efficient process for industrial furfural production from lignocellulosic biomass (Bamufleh et al 2013).…”

Section: Introductionmentioning

confidence: 99%

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Efficient Production of Furfural from Corncob by an Integrated Mineral-Organic-Lewis Acid Catalytic Process

Zhang

et al. 2017

BioResources

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An M-O-L acid (mineral acid, organic acid, and Lewis acid)-catalyzed integrated process for furfural production from corncob was proposed to improve corncob conversion and furfural selectivity. First, the co-catalysts of sulfuric acid and acetic acid were investigated for their impact on furfural production. Sulfuric acid as a pretreatment catalyst was mixed with corncob before the experiment. Acetic acid, which is a byproduct of hemicellulose hydrolysis, was fed together with steam. The results showed that the cooperation of sulfuric acid and acetic acid decreased the total acid consumption dramatically. FeCl3·6H2O was also investigated as a cocatalyst in an effort to enhance the conversion of xylose to furfural and decrease furfural degradation. The integrated catalytic process achieved the highest furfural yield of 68.04% through the use of M-O-L acid under a reaction temperature of 180°C, 3v% acetic acid, 4.0 wt.% sulfuric acid of 0.6 mL/g liquid to solid ratio, and 5 g FeCl3·6H2O per 100 g of biomass.

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Section: Impact Of Sulfuric Acidmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Efficient Production of Furfural from Corncob by an Integrated Mineral-Organic-Lewis Acid Catalytic Process

Zhang

et al. 2017

BioResources

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“…In previous studies, industrial hemp was effectively pretreated with application of 1-3 % NaOH (121 °C) and 1-3 % H 2 O 2 (90-121 °C). In these cases, lignin solubilization amounted to 42-51 % and 35-47 % after alkaline (NaOH) and oxidative (H 2 O 2 ) pretreatment, respectively [8,12]. However, hemp pretreatment by alkaline/oxidative method led to simultaneous release of C5 sugars into pretreatment liquors as well as sugar losses.…”

Section: Introductionmentioning

confidence: 99%

“…Currently, an increased interest on hemp research and cultivation has been observed [3,4]. Besides its traditional usage as isolation material and substrate used in textile industry, hemp has been tested as solid fuel as well as feedstock for biofuels (biogas, biohydrogen, bioethanol) [5,6] or bio-chemicals (succinic and lactic acid, furfural) production [7][8][9]. Additionally, hemp was tested as feedstock for integrated biofuels (bioethanol and biogas) [10] as well as bioethanol coupled with succinic acid production [11,12].…”

Section: Introductionmentioning

confidence: 99%

“…Due to low sugar content in pretreatment liquors after alkaline/oxidative method, such residues are very frequently not utilized for biofuels and chemicals production, which causes significant losses of hemicellulosic fraction, i.e. even 36-41 % and 31-42 % for alkaline and oxidative method, respectively [8,12]. One of the solution constitutes application of organic solvents (organosolv pretreatment), especially glycerol, which can easily penetrate into the biomass and provides an effective reagent for biomass fractionation, minimizing sugar losses and improving enzymatic hydrolysis of cellulose [14,15].…”

Section: Introductionmentioning

confidence: 99%

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Integrated Production of Biofuels and Succinic Acid from Biomass after Thermochemical Pretreatments

Kuglarz

Grűbel

2018

Ecological Chemistry and Engineering S

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The aim of this study was to develop an effective thermochemical method for treatment of industrial hemp, in order to increase its bioconversion to biofuels and bio-products. Industrial hemp was subjected to various thermochemical pretreatments using: alkaline (3 % NaOH), oxidative (3 % H2O2 at pH 11.5) and glycerol-based methods (70-90 % of glycerol, 1-3 % NaOH), prior to enzymatic hydrolysis with Cellic® CTec2/Cellic® HTec2 (15 FPU∙g−1 glucan). Innovative pretreatment with glycerol fraction (80 % glycerol content, 2 % NaOH, 12.5 % biomass loading) showed to be superior over commonly used alkaline and oxidative methods with respect to by-products generation and sugar losses. Integrated process of ethanol production from enriched cellulose fraction (172 kg EtOH∙Mg−1 of dry hemp) and succinic production from xylose-rich residue after ethanol fermentation (59 kg∙Mg−1 of dry hemp) allowed to convert about 97 % of sugars released (glucose and xylose) during enzymatic hydrolysis of pre-treated biomass. The present study showed that it is possible to replace 50 % of the costly yeast extract, used during succinic fermentation as nitrogen source, by alternative nitrogen source (rapeseed cakes) without significant deterioration of succinic yield. Pretreatment liquor after lignin precipitation (52 kg∙Mg−1 of biomass treated) exhibited a high biodegradability (92 %) and allowed to produce 420 m3 CH4/Mg VS). Results obtained in this study clearly document the possibility of biofuels (bioethanol, biogas) and bio-chemicals production from industrial hemp, in a biorefinery approach.

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Sustainable Catalytic Strategies for C5-Sugars and Biomass Hemicellulose Conversion Towards Furfural Production

Lopes

Morais

Bogel‐Łukasik

2017

Production of Platform Chemicals From Sustainable Resources

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Effect of aluminium sulphate-catalysed hydrolysis process on furfural yield and cellulose degradation of Cannabis sativa L. shives

Cited by 30 publications

References 29 publications

Efficient Production of Furfural from Corncob by an Integrated Mineral-Organic-Lewis Acid Catalytic Process

Efficient Production of Furfural from Corncob by an Integrated Mineral-Organic-Lewis Acid Catalytic Process

Integrated Production of Biofuels and Succinic Acid from Biomass after Thermochemical Pretreatments

Sustainable Catalytic Strategies for C5-Sugars and Biomass Hemicellulose Conversion Towards Furfural Production

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