Chemocatalytic Conversion of Ethanol into Butadiene and Other Bulk Chemicals

Angelici, Carlo; Weckhuysen, Bert M.; Bruijnincx, Pieter C. A.

doi:10.1002/cssc.201300214

Cited by 398 publications

(357 citation statements)

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“…Although, novel biochemical, thermo-catalytic, and hybrid routes are being developed to produce drop-in fuels and fuel additives to meet the infrastructure and other requirements (Huber et Figure 1 shows that ethanol derived from cellulosic biomass can also be used to produce other fuel candidates such as butanol, gasoline, hydrogen, diesel, and others (Whitcraft et al, 1983;Costa et al, 1985;Deluga et al, 2004;Narula et al, 2015;Riittonen et al, 2015). Moreover, ethanol can also serve as a precursor for several other chemicals and intermediates that are currently derived from non-renewable resources (Angelici et al, 2013;Sun and Wang, 2014). …”

Section: Why Ethanol?mentioning

confidence: 99%

Recent updates on lignocellulosic biomass derived ethanol - A review

et al. 2016

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HIGHLIGHTSCellulosic biomass is the only source for sustainable fuels.Ethanol is a promising fuel candidate for near/long term applications.Ethanol can also serve as a precursor for other fuels and chemicals.However, processing cost for 2G ethanol is still high.Thus, urgent research efforts are needed to bring the cost down. Lignocellulosic (or cellulosic) biomass derived ethanol is the most promising near/long term fuel candidate. In addition, cellulosic biomass derived ethanol may serve a precursor to other fuels and chemicals that are currently derived from unsustainable sources and/or are proposed to be derived from cellulosic biomass. However, the processing cost for second generation ethanol is still high to make the process commercially profitable and replicable. In this review, recent trends in cellulosic biomass ethanol derived via biochemical route are reviewed with main focus on current research efforts that are being undertaken to realize high product yields/titers and bring the overall cost down. GRAPHICAL ABSTRACT ARTICLE INFO ABSTRACT

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Section: Why Ethanol?mentioning

confidence: 99%

Recent updates on lignocellulosic biomass derived ethanol - A review

et al. 2016

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“…As expected, an increase in reaction temperature increased ethene selectivity, Figure 2(a), and decreased DEE selectivity, Figure 2(b), ethanol dehydration to ethene is endothermic and to DEE is exothermic. [7,38] Even though the mechanism of DEE formation is still discussed in the literature, for instance, regarding whether it involves acid-base pairs, [39,40] Brønsted acid sites and/or Lewis acid sites, [40] it is understood that DEE formation should involve the reaction of the two nearest chemisorbed ethanol moieties. [41] On the other hand, ethene formation should occur through a concerted mechanism, where the methyl hydrogen of the ethoxide species, chemisorbed on a Lewis [41] or Brønsted acid site, [42] is abstracted by the adjacent Brønsted basic site.…”

Section: Reaction Temperature and Whsv Effectmentioning

confidence: 99%

“…The effect of calcination steps removal was further investigated through 7 Li MAS NMR spectroscopy. Figure S9(a) shows spectra for samples 1.2-Li/ZrZn/MgO-SiO 2-1 and 1.2-Li/ZrZn/MgO-SiO2-1 prepared with only 1 calcination step after ZrO2 and ZnO addition.…”

Section: Catalyst Acidity Modificationmentioning

confidence: 99%

“…[3,4] Besides environmental concerns as a result of the use of petroleumderived hydrocarbons, the need for a new route to 1,3-BD is further exacerbated due to the possible future shortfall in supply due to the changes of feedstock from naphtha to ethane in the U.S. [5,6] The catalytic conversion of ethanol into 1,3-BD is an attractive alternative, due to the availability of bioethanol which is expected to significantly increase over the next few years from fermentation of sugar rich waste materials (second generation bioethanol). [1,5,7,8] For example in Brazil alone, 23.4 billion litres of bioethanol were produced in 2014. [9] The route most widely accepted to account for 1,3-BD production from ethanol involves five consecutive reactions.…”

Section: Introductionmentioning

confidence: 99%

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Ethanol to 1,3‐Butadiene Conversion by using ZrZn‐Containing MgO/SiO₂ Systems Prepared by Co‐precipitation and Effect of Catalyst Acidity Modification

et al. 2016

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Abstract:The conversion of ethanol to 1,3-butadiene (1,3-BD) has been investigated over ZrO2 and ZnO containing magnesia silica oxides prepared by co-precipitation method at different Mg-to-Si molar ratios. The effect of reaction temperature and ethanol flow rate was investigated. The catalyst acidity was modified through the addition of alkali metals (Na, K and Li) to the final materials. Catalysts were characterised by nitrogen physisorption analysis, Xray diffraction, scanning electron microscopy with energy dispersive X-ray, temperature programmed desorption of ammonia, infrared spectroscopy and 29 Si/( 7 Li) NMR spectroscopy. The catalytic results showed that the controlled reduction of catalyst acidity allows suppressing of ethanol dehydration, whilst increasing 1,3-BD selectivity. The best catalytic performance achieved 72 mol % for the combined 1,3-BD and acetaldehyde selectivity.

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“…C4H6 is also a by product of C2H4 production through cracking of hydrocarbons. C4H6 production from bio ethanol is a promising alternative that has been industrially implemented prior to the installation of naphtha cracking technologies; ethanol to C4H6 processes have been used since 1920, constituting the main production practice until the end of World War II [22,100]. Main routes of this process include dehydrogenation, dehydration, and condensation over suitable catalysts, either in one step (i.e., Lebedev approach) (Scheme 5) or two step processes (i.e., Ostromisslenski C 4 H 6 is also a by-product of C 2 H 4 production through cracking of hydrocarbons.…”

Section: Butadiene (C4h6)mentioning

confidence: 99%

Olefins from Biomass Intermediates: A Review

Zacharopoulou

Lemonidou

2017

Catalysts

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Over the last decade, increasing demand for olefins and their valuable products has prompted research on novel processes and technologies for their selective production. As olefins are predominately dependent on fossil resources, their production is limited by the finite reserves and the associated economic and environmental concerns. The need for alternative routes for olefin production is imperative in order to meet the exceedingly high demand, worldwide. Biomass is considered a promising alternative feedstock that can be converted into the valuable olefins, among other chemicals and fuels. Through processes such as fermentation, gasification, cracking and deoxygenation, biomass derivatives can be effectively converted into C 2 -C 4 olefins. This short review focuses on the conversion of biomass-derived oxygenates into the most valuable olefins, e.g., ethylene, propylene, and butadiene.

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Chemocatalytic Conversion of Ethanol into Butadiene and Other Bulk Chemicals

Cited by 398 publications

References 105 publications

Recent updates on lignocellulosic biomass derived ethanol - A review

Recent updates on lignocellulosic biomass derived ethanol - A review

Ethanol to 1,3‐Butadiene Conversion by using ZrZn‐Containing MgO/SiO₂ Systems Prepared by Co‐precipitation and Effect of Catalyst Acidity Modification

Olefins from Biomass Intermediates: A Review

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Chemocatalytic Conversion of Ethanol into Butadiene and Other Bulk Chemicals

Cited by 398 publications

References 105 publications

Recent updates on lignocellulosic biomass derived ethanol - A review

Recent updates on lignocellulosic biomass derived ethanol - A review

Ethanol to 1,3‐Butadiene Conversion by using ZrZn‐Containing MgO/SiO2 Systems Prepared by Co‐precipitation and Effect of Catalyst Acidity Modification

Olefins from Biomass Intermediates: A Review

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Ethanol to 1,3‐Butadiene Conversion by using ZrZn‐Containing MgO/SiO₂ Systems Prepared by Co‐precipitation and Effect of Catalyst Acidity Modification