Computational Studies of the Thermochemistry for Conversion of Glucose to Levulinic Acid

Assary, Rajeev S.; Redfern, Paul C.; Hammond, Jeff R.; Greeley, Jeffrey; Curtiss, Larry A.

doi:10.1021/jp101418f

Cited by 112 publications

(127 citation statements)

References 39 publications

Supporting

Mentioning

116

Contrasting

Order By: Relevance

“…[33][34][35][36] Similar to previous studies, [37][38][39][40] the periodic model of BEA zeolite corresponded to polymorph A. [41] The optimized parameters of the tetragonal BEA unit cell were a = b = 12.657 and c = 26.396 .…”

supporting

confidence: 68%

“…In the case of Brønsted acid catalysis, the unfavorable protonation of the pyranyl O5 site of GP may lead to the formation of fructose. [33,34,42,43] When the reaction is promoted by Lewis acids, the direct coordination of the O sites of GP to the active site is the key to the selective FF formation. [13,20,23,44,45] Previously, the isomerization by a heterogeneous Sn-BEA catalyst has been postulated to proceed through the O5-coordination of GP to the lattice Sn site (Figure 2 a) followed by a concerted O1H deprotonation and ring-opening reactions.…”

Section: Resultsmentioning

confidence: 99%

See 1 more Smart Citation

The Mechanism of Glucose Isomerization to Fructose over Sn‐BEA Zeolite: A Periodic Density Functional Theory Study

Yang¹,

Pidko²,

Hensen³

2013

ChemSusChem

132

165

View full text Add to dashboard Cite

The isomerization of glucose to fructose in the presence of Sn-containing zeolite BEA (beta polymorph A) was studied by periodic DFT calculations. Focus was placed on the nature of the active site and the reaction mechanism. The reactivities of the perfect lattice Sn(IV) site and the hydroxylated SnOH species are predicted to be similar. The isomerization activity of the latter can be enhanced by creating an extended silanol nest in its vicinity. Besides the increased Lewis acidity and coordination flexibility of the Sn center, the enhanced reactivity in this case is ascribed to the reaction environment that promotes activation of the confined sugar intermediates through hydrogen bonding. The resulting multidentate activation of the substrate favors the rate-determining hydrogen-shift reaction. These findings suggest the important role of defect lattice sites in Sn-BEA for catalytic glucose isomerization.

show abstract

supporting

confidence: 68%

Section: Resultsmentioning

confidence: 99%

The Mechanism of Glucose Isomerization to Fructose over Sn‐BEA Zeolite: A Periodic Density Functional Theory Study

Yang¹,

Pidko²,

Hensen³

2013

ChemSusChem

132

165

View full text Add to dashboard Cite

show abstract

“…45,46 Th e effi cient and optimised production of levulinic Th e thermochemistry of conversion of glucose to levulinic acid through fructofuranosyl intermediates was investigated by Assary and co-workers. 64 Th ey found that the fi rst two dehydration steps are highly endothermic likely indicating these to be key steps in controlling the overall progress of the reaction, while the other steps, including the additional water elimination and rehydration to form levulinic acid, are exothermic. Th e dehydration reaction steps were predicted to be more favourable thermodynamically under elevated temperatures and aqueous reaction environments.…”

Section: Lignocellulosic Feedstocksmentioning

confidence: 99%

The conversion of lignocellulosics to levulinic acid

Rackemann

Doherty

2011

Biofuels Bioprod Bioref

590

361

View full text Add to dashboard Cite

Biomass represents an abundant and relatively low cost carbon resource that can be utilized to produce platform chemicals such as levulinic acid. Current processing technology limits the cost-effective production of levulinic acid in commercial quantities from biomass. The key to improving the yield and effi ciency of levulinic acid production from biomass lies in the ability to optimize and isolate the intermediate products at each step of the reaction pathway and reduce re-polymerization and side reactions. New technologies (including the use of microwave irradiation and ionic liquids) and the development of highly selective catalysts would provide the necessary step change for the optimization of key reactions. A processing environment that allows the use of biphasic systems and/or continuous extraction of products would increase reaction rates, yields and product quality. This review outlines the chemistry of levulinic acid synthesis and discusses current and potential technologies for producing levulinic acid from lignocellulosics.

show abstract

“…In contrast, reactions of water-soluble sugars with solid acid catalysts have been extensively studied [8,14,65,78,87,88,115]. In general, the heterogeneous catalytic system could convert water-soluble sugars to organic acids by shape-selective, solid acid-catalyzed processes at low temperatures.…”

Section: Heterogeneous Catalystsmentioning

confidence: 99%

Catalytic Conversion of Lignocellulosic Biomass to Value-Added Organic Acids in Aqueous Media

Lin

Liu

et al. 2014

Green Chemistry and Sustainable Technology

View full text Add to dashboard Cite

The transition from today's fossil-based economy to a sustainable economy based on renewable biomass is driven by the concern of climate change and anticipation of dwindling fossil resources. Although biofuels are the central theme of the transition, biomass resources cannot completely replace petroleum. It is projected that biofuels can only supply up to 30 % of today's transportation fuel market even if all available domestic biomass resources are used for the production of liquid fuels. Therefore, transformation of biomass into high-value-added chemicals is advantageous to secure optimal use of the abundant, but limited, biomass resources from the economical and ecological perspective. Industry is increasingly considering bio-based chemical production as an attractive area for investment. The potential for chemical and polymer production from biomass is substantial. The US Department of Energy recently issued a report which listed 12 chemical building blocks considered as potential building blocks for the future. Organic acids (e.g., succinic, lactic, levulinic acid, etc.) are among the widely spread ''platform-molecules,'' which may be further converted into possibly derivable high-value-added chemicals. The transition from a fossil chemical industry to a renewable chemical industry will likewise depend on our ability to focus research and development efforts on the most promising alternatives. In this chapter, we review the emerging technologies on catalytic conversion of biomass to value-added organic acids in aqueous media.

show abstract

Computational Studies of the Thermochemistry for Conversion of Glucose to Levulinic Acid

Cited by 112 publications

References 39 publications

The Mechanism of Glucose Isomerization to Fructose over Sn‐BEA Zeolite: A Periodic Density Functional Theory Study

The Mechanism of Glucose Isomerization to Fructose over Sn‐BEA Zeolite: A Periodic Density Functional Theory Study

The conversion of lignocellulosics to levulinic acid

Catalytic Conversion of Lignocellulosic Biomass to Value-Added Organic Acids in Aqueous Media

Contact Info

Product

Resources

About