Direct Conversion of Cellulose into Ethyl Lactate in Supercritical Ethanol–Water Solutions

Yang, Lisha; Yang, Xiaokun; Tian, Elli; Lin, Hongfei

doi:10.1002/cssc.201500855

Cited by 40 publications

(23 citation statements)

References 60 publications

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“…In addition, the relatively strong Lewis acidity, combined with weak Brønsted acidity of a single catalyst, was also crucial for the direct conversion of cellulose into LA/AL in one pot . The weak Brønsted acid sites could promote the hydrolysis of cellulose and dehydration of important intermediates (trioses) for LA/AL formation, while inhibiting the formation of furanic compounds derived from fructose/glucose dehydration, wherein the hydrolysis of cellulose was assumed to be the rate‐determining step during the whole conversion process . As high as 33 % yield of EL was obtained from cellulose in ethanol/water (95/5 v/v) with Zr‐SBA‐15 at 260 °C within 6 h .…”

Section: Catalytic Processes With a Decrease In Carbon Numbermentioning

confidence: 99%

“…The weak Brønsted acid sites could promote the hydrolysis of cellulose and dehydration of important intermediates (trioses) for LA/AL formation, while inhibiting the formation of furanic compounds derived from fructose/glucose dehydration, wherein the hydrolysis of cellulose was assumed to be the rate‐determining step during the whole conversion process . As high as 33 % yield of EL was obtained from cellulose in ethanol/water (95/5 v/v) with Zr‐SBA‐15 at 260 °C within 6 h . The high EL yield attained resulted from the synergistic effect of the relatively strong Lewis and weak Brønsted acidity of Zr‐SBA‐15, and the presence of water, together with the surface hydrophobicity of Zr‐SBA‐15, facilitated cleavage of the β‐1,4‐glycosidic bond of cellulose.…”

Section: Catalytic Processes With a Decrease In Carbon Numbermentioning

confidence: 99%

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Catalytic Upgrading of Biomass‐Derived Sugars with Acidic Nanoporous Materials: Structural Role in Carbon‐Chain Length Variation

Saravanamurugan

et al. 2018

ChemSusChem

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Shifting from petroleum‐based resources to inedible biomass for the production of valuable chemicals and fuels is one of the significant aspects in sustainable chemistry for realizing the sustainable development of our society. Various renowned biobased platform molecules, such as 5‐hydroxymethylfurfural, furfural, levulinic acid, and lactic acid, are successfully accessible from the transformation of biobased sugars. To achieve the specific reaction routes, heterogeneous nanoporous acidic materials have served as promising catalysts for the conversion of bio‐sugars in the past decade. This Review summarizes advances in various nanoporous acidic materials for bio‐sugar conversion, in which the number of carbon atoms is variable and controllable with the assistance of the switchable structure of nanoporous materials. The major focus of this Review is on possible reaction pathways/mechanisms and the relationships between catalyst structure and catalytic performance. Moreover, representative examples of catalytic upgrading of biobased platform molecules to biochemicals and fuels through selective C−C cleavage and coupling strategies over nanoporous acidic materials are also discussed.

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Section: Catalytic Processes With a Decrease In Carbon Numbermentioning

confidence: 99%

Section: Catalytic Processes With a Decrease In Carbon Numbermentioning

confidence: 99%

Catalytic Upgrading of Biomass‐Derived Sugars with Acidic Nanoporous Materials: Structural Role in Carbon‐Chain Length Variation

Saravanamurugan

et al. 2018

ChemSusChem

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“…Zr-SBA-15 was synthesized according to the procedure described in reference [27] and had been well implemented in our previous articles. [28,29] Briefly, 2 g of Pluronic P123 was added to 75 ml of 1.6 M HCl solution. The mixture was stirred at 40°C for 3 hours until all P123 was dissolved.…”

Section: Catalyst Preparationmentioning

confidence: 99%

Catalytic Transfer Hydrogenation of Furfural for the Production of Ethyl Levulinate: Interplay of Lewis and Brønsted Acidities

et al. 2018

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Ethyl levulinate is sought after due to its applications as a fuel additive in biodiesel fuels. Currently it's industrially produced using harmful, highly reactive acids like H2SO4 and HCl, which are used to produce levulinic acid, the common precursor used for EL production. Herein, ethyl levulinate is produced from the synergistic effect of Brønsted and Lewis acids, which catalyze the hydrogenation of furfural leading to the alternative precursor for EL production, furfuryl alcohol. The subsequent ethanolysis reaction of furfuryl alcohol to produce EL, is also enhanced by using an optimal ratio of Brønsted to Lewis acids. Ethanol is chosen as the sacrificial hydrogen donor for proton transfer hydrogenation since it is environmentally friendly, more abundant and affordable than other alcohols that are commonly used for large‐scale production processes. The tandem catalytic reaction can be effectively used to sustainably and responsibly produce ethyl levulinate in relatively short reaction times.

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“…In addition, 31.2% ML yield could be also obtained from real biomass sugar cane bagasse at 190°C within 6 h. However, lower yields of ML were achieved from glucose (15.7%) and sucrose (14.7%), may be derived from the strong acidity of SnCl 2 ·2H 2 O-ZnCl 2 which would transform many monosaccharides and disaccharides into dark tars. On the other hand, Zr-SBA-15 heterogeneous catalysts developed by Lin group, could not only exhibit good yields of ML form monosaccharides and disaccharides ( Table 3, Entry 8) [113], but also perform well from cellulose directly in 95% methanol solvent [113] and in 95% ethanol [122], respectively. e addition of a little amount of water (5 wt%) along with the weak Brønsted acids of Zr-SBA-15, was believed to facilitate the hydrolysis of cellulose.…”

Section: Cellulose To Lactatesmentioning

confidence: 99%

Chemocatalytic Production of Lactates from Biomass-Derived Sugars

Zhang

et al. 2018

International Journal of Chemical Engineering

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In recent decades, a great deal of attention has been paid to the exploration of alternative and sustainable resources to produce biofuels and valuable chemicals, with aims of reducing the reliance on depleting confined fossil resources and alleviating serious economic and environmental issues. In line with this, lignocellulosic biomass-derived lactic acid (LA, 2-hydroxypropanoic acid), to be identified as an important biomass-derived commodity chemical, has found wide applications in food, pharmaceuticals, and cosmetics. In spite of the current fermentation of saccharides to produce lactic acid, sustainability issues such as environmental impact and high cost derived from the relative separation and purification process will be growing with the increasing demands of necessary orders. Alternatively, chemocatalytic approaches to manufacture LA from biomass (i.e., inedible cellulose) have attracted extensive attention, which may give rise to higher productivity and lower costs related to product work-up. is work presents a review of the state-of-the-art for the production of LA using homogeneous, heterogeneous acid, and base catalysts, from sugars and real biomass like rice straw, respectively. Furthermore, the corresponding bio-based esters lactate which could serve as green solvents, produced from biomass with chemocatalysis, is also discussed. Advantages of heterogeneous catalytic reaction systems are emphasized. Guidance is suggested to improve the catalytic performance of heterogeneous catalysts for the production of LA.

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Direct Conversion of Cellulose into Ethyl Lactate in Supercritical Ethanol–Water Solutions

Cited by 40 publications

References 60 publications

Catalytic Upgrading of Biomass‐Derived Sugars with Acidic Nanoporous Materials: Structural Role in Carbon‐Chain Length Variation

Catalytic Upgrading of Biomass‐Derived Sugars with Acidic Nanoporous Materials: Structural Role in Carbon‐Chain Length Variation

Catalytic Transfer Hydrogenation of Furfural for the Production of Ethyl Levulinate: Interplay of Lewis and Brønsted Acidities

Chemocatalytic Production of Lactates from Biomass-Derived Sugars

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