Direct Conversion of Carbohydrates into Ethyl Levulinate with Potassium Phosphotungstate as an Efficient Catalyst

Zhao, Shiqiang; Xu, Guoqiang; Chang, Chun; Fang, Shuqi; Liu, Ze; Du, Fang

doi:10.3390/catal5041897

Cited by 52 publications

(43 citation statements)

References 31 publications

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“…EDGP isomerization to EDFF is a Lewis acid catalyzed reaction 87 as shown in Figure-6. Similar to the results obtained on ILs, several research groups have experimented with metal doped K-HPA (H3PW12O40) and measured a low EL yield (14.5%, Table-4, entry 12) on glucose ethanolysis 146 . A combination of both Brønsted and Lewis acidity is therefore essential for glucose conversion to EL.…”

Section: Synthesis Of El From Monosaccharides and Polysaccharidessupporting

confidence: 64%

“…A combination of both Brønsted and Lewis acidity is therefore essential for glucose conversion to EL. The Lewis acidity of HPAs is expected to be enhanced by introducing metal dopants which needs to be further explored for glucose ethanolysis reaction 146 . Interestingly, compared to IL, on HPA, the time (120 min) required to obtain this yield was shorter 140,145 , which can be attributed to the presence of appreciable amount (0.03 mmol/g) of Lewis acid sites (Brønsted to Lewis site ratio, B/L > 58) 150 .…”

Section: Synthesis Of El From Monosaccharides and Polysaccharidesmentioning

confidence: 99%

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Catalytic and mechanistic insights into the production of ethyl levulinate from biorenewable feedstocks

et al. 2016

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The importance of ethyl levulinate (EL) as a fuel additive and a potential biomassderived platform molecule is noteworthy. EL is obtained from the esterification of levulinic acid (LA) in presence of ethanol. Besides LA, the acid-catalyzed ethanolysis reaction to produce EL is carried out on a variety of biomass-derived substrates which include; furfuryl alcohol (FAL), chloromethyl furfural, monosaccharides, polysaccharides and lignocellulosic biomass. The acid catalysts employed for such conversions covers a wide range of structure and properties. The nature of acid catalysts and the key intermediates formed during the reaction dictates the overall yield of the desired product. For example, in the ethanolysis reaction of FAL to produce EL, diethyl ether (DEE) and ethoxymethylfuran (EMF) produced as side products are suggested to influence the selectivity of EL. Similarly, in the ethanolysis of glucose, formation of ethyl-Dglucopyranoside (EDGP) resulted into a slow conversion to produce EL. The review, therefore; is focused on highlighting the importance of catalyst structure, acidity, reaction mechanism and the role of key intermediates in the production of EL from biorenewable resources.EL could either be synthesized directly from biomass or via the transformation of LA, or FAL 20 or chloromethyl furfural (CMF) 23 . All of the suggested reaction routes essentially contain an ethanolysis step in the presence of an acid catalyst. In general, an understanding of the mechanistic routes of product formation, dictates the development of a suitable process for achieving higher yield 24,25 . This could be further strengthened by the design of a suitable homogeneous acid, solid acid or ionic liquid based acid catalysts. On catalytic processing, EL could be converted into an array of higher value chemicals. This review comprehensively covers all the suggested ways of EL production and applications detailing key mechanistic insights, catalytic properties and reaction conditions. Importance of EL as a Fuel AdditiveAlkyl levulinates have shown considerable promises for blending in gasoline and diesel engines, owing to their reduced sulfur content, high lubricity, improved flow properties and flash point stability 20 . The candidate LA esters for this application are methyl, ethyl 26 and butyl levulinates, 23 measuring anti-knocking index of value 106.5, 107.5 and 102.5 respectively 27 . Out of three levulinates, methyl levulinate (ML) is miscible with water and is difficult to separate. With gasoline, ML is lesser miscible and under cold flow conditions is not suitable to blend.Compared to butyl levulinate (BL), EL shows better solubility with diesel range fuels containing higher aromatics 14 . Moreover, NOx emissions were lowered by about 4% on EL blend in diesel as compared to the BL blend. Higher NOx emissions could be attributed to the dilution of lube oil and deposits in combustion chamber, which was observed to be a major problem with BL blended fuels. Furthermore, when propanol or higher alcohols are used for the...

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Section: Synthesis Of El From Monosaccharides and Polysaccharidessupporting

confidence: 64%

Section: Synthesis Of El From Monosaccharides and Polysaccharidesmentioning

confidence: 99%

Catalytic and mechanistic insights into the production of ethyl levulinate from biorenewable feedstocks

et al. 2016

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“…The first step for cellulose valorization is based on its depolymerisation into oligomers and glucose followed by catalytic reactions (hydrogenation, oxidations, esterification, etc.) for the manufacture of a pool of chemicals such as C6-C2 polyols, levulinic acid, hydroxymethylfurfural (HMF), among others ( [25][26][27][28][29] and "references within"). Polyols, owing to their peculiar chemical properties, could represent an important resource for production of several building-block chemicals.…”

Section: Introductionmentioning

confidence: 99%

“…Therefore, its utilization for chemicals production has not a negative impact on the food supply. For this reason, its conversion into added-value chemicals and/or fuel components is one of the core technologies in the modern bio-refinery [25][26][27][28]. The first step for cellulose valorization is based on its depolymerisation into oligomers and glucose followed by catalytic reactions (hydrogenation, oxidations, esterification, etc.)…”

Section: Introductionmentioning

confidence: 99%

Upgrading Lignocellulosic Biomasses: Hydrogenolysis of Platform Derived Molecules Promoted by Heterogeneous Pd-Fe Catalysts

et al. 2017

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Abstract:This review provides an overview of heterogeneous bimetallic Pd-Fe catalysts in the C-C and C-O cleavage of platform molecules such as C2-C6 polyols, furfural, phenol derivatives and aromatic ethers that are all easily obtainable from renewable cellulose, hemicellulose and lignin (the major components of lignocellulosic biomasses). The interaction between palladium and iron affords bimetallic Pd-Fe sites (ensemble or alloy) that were found to be very active in several sustainable reactions including hydrogenolysis, catalytic transfer hydrogenolysis (CTH) and aqueous phase reforming (APR) that will be highlighted. This contribution concentrates also on the different synthetic strategies (incipient wetness impregnation, deposition-precipitaion, co-precipitaion) adopted for the preparation of heterogeneous Pd-Fe systems as well as on the main characterization techniques used (XRD, TEM, H 2 -TPR, XPS and EXAFS) in order to elucidate the key factors that influence the unique catalytic performances observed.

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“…Along these lines, Wang et al proposed the utilization of cheap and environmentally friendly Nb/Al oxide catalysts for the conversion of kiwifruit waste to levulinic acid [7]. Additionally, the direct conversion of carbohydrates into ethyl levulinate using potassium phosphotungstate as efficient catalyst was reported by Zhao et al [8]. Further conversion of levulinic acid to gamma-valerolactone (GVL) could also take place efficiently on nickel/alumina catalysts [9].…”

mentioning

confidence: 99%

Catalytic Conversion of Biomass

Luque

Balu

2016

Catalysts

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Direct Conversion of Carbohydrates into Ethyl Levulinate with Potassium Phosphotungstate as an Efficient Catalyst

Cited by 52 publications

References 31 publications

Catalytic and mechanistic insights into the production of ethyl levulinate from biorenewable feedstocks

Catalytic and mechanistic insights into the production of ethyl levulinate from biorenewable feedstocks

Upgrading Lignocellulosic Biomasses: Hydrogenolysis of Platform Derived Molecules Promoted by Heterogeneous Pd-Fe Catalysts

Catalytic Conversion of Biomass

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