Catalytic Deoxygenation of Xylitol to Renewable Chemicals: Advances on Catalyst Design and Mechanistic Studies

Xia, Qineng; Jin, Xin; Zhang, Guangyu; Liu, Mengyuan; Wang, Jinyao; Li, Yushan; Fang, Tianqi; Ding, Jie; Zhang, Dongpei; Meng, Kexin; Chen, Xiaobo; Yang, Chaohe

doi:10.1002/tcr.202000101

Cited by 12 publications

(7 citation statements)

References 37 publications

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“…42,43 Bindwal and Vaidya reported the hydrogenolysis of levoglucosan over a Ru/C catalyst in water as a solvent. 44 The main products were 1,2-propanediol and ethylene glycol with a combined yield of 35%-C (94.8% conversion) at 413 K. These glycols can also be produced by the hydrogenolysis of various sugars and sugar alcohols such as cellulose, 45,46 sorbitol, [47][48][49] xylitol, 50 and glycerol. 51,52 The combined yields Fig.…”

Section: Levoglucosan and Levoglucosenonementioning

confidence: 99%

Hydrodeoxygenation of potential platform chemicals derived from biomass to fuels and chemicals

et al. 2022

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Section: Levoglucosan and Levoglucosenonementioning

confidence: 99%

Hydrodeoxygenation of potential platform chemicals derived from biomass to fuels and chemicals

et al. 2022

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“…Traditionally, the petrochemical refinery has been the major route for the production of chemicals and fuels in human civilization. To overcome global warming and the depletion of fossil resources, green technology using biomass and biobased solid wastes as raw material for organic chemicals, so-called biorefinery, has been developed widely, since biomass is the only carbon-neutral and renewable source of organic carbon. , Due to the intrinsic properties (the complex mixture of polymers with various minor components) of raw biomass, the use of “platform chemicals”, which can be readily synthesized in pure form from biomass, as intermediates is a typical approach to synthesizing useful chemicals from biomass. , Sugar alcohols, polyols with an O/C ratio of 1, are typical platform chemicals and produced from these resources such as glycerol from the manufacturing process of biodiesel fuel, erythritol from sugars by fermentation, xylitol from hemicellulose by hydrolytic hydrogenation, and sorbitol from sugars or cellulose by (hydrolytic) hydrogenation . Many other polyols can also be produced from biomass via reduction of sugars or sugar-derived platform chemicals such as 1,2-propanediol from sugars, pentanediols from furfural, , 1,4-pentanediol from levulinic acid, and hexanetriols/hexanetetraols from sugar derivatives .…”

Section: Introductionmentioning

confidence: 99%

Synthesis of Secondary Monoalcohols from Terminal Vicinal Alcohols over Silica-Supported Rhenium-Modified Ruthenium Catalyst

Liu

Sekine

Nakagawa

et al. 2022

ACS Sustainable Chem. Eng.

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The selective synthesis of secondary alcohols from 1,2-alkanediol by C−O hydrogenolysis, which has been less investigated than the synthesis of primary alcohols, was investigated with Ru-based catalysts and 1,2-propanediol (1,2-PrD) as a model substrate. The modification of Ru/SiO 2 with ReO x achieved significant improvement of activity. The hydrogenolysis of 1,2-PrD over Ru−ReO x /SiO 2 (Re/Ru = 0.5) initially formed both 2-propanol (2-PrOH) and 1-propanol (1-PrOH) with similar selectivity along with the formation of ≤ C2 compounds, and then 1-PrOH was preferably converted to propane; as a result, only 2-PrOH remained in the liquid phase with 23% yield at longer reaction time. This catalyst was reusable at least twice. The characterization with H 2 -TPR, XRD, TEM-EDX, XANES, and EXAFS showed that the Ru species in the Ru−ReO x /SiO 2 catalysts were completely reduced in the reaction conditions, while a part of Re species were also reduced to partially reduced monomeric species (Re δ+ O x ) without Re−Re direct bond located on the surface of Ru metal particles. This ReO x -modified Ru metal surface probably works as the active sites. The excess Re species was reduced to large Re metal particles; however, these Re metal particles are not involved in the catalysis.

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“…[52] For ACÀ HNO 3 the ratio of O/C on the surface increases from 5.2 • 10 À 2 (AC) to 13.0 • 10 À 2 and nitrogen is introduced with a ratio of N/C of 1. ChemCatChem sp 3 -hybridized carbon on the surface, implying that the acid treatment creates defects in the aromatic carbon structure decreasing the degree of graphitization (Figure 3b). In the N 1s region, two signals occur which are assigned to NÀ O species such as in nitro or nitroso groups (405.7 eV) [53] and NÀ C species such as pyridinic, pyrollic and graphitic nitrogen (400.2 eV) (Figure 3c).…”

Section: Role Of Thementioning

confidence: 99%

“…The production of glycols, used as monomers in the chemical industry, offers the possibility to substitute fossil by renewable raw materials [1–2] . Sugar alcohols such as the hemicellulose derived platform molecule xylitol (XYL) can be used as feedstock [3] . The conversion to ethylene and propylene glycol (EG and PG) involves many reaction mechanisms such as metal catalyzed dehydrogenation and hydrogenation or base promoted retro‐aldol splitting (Scheme 1).…”

Section: Introductionmentioning

confidence: 99%

“…[1][2] Sugar alcohols such as the hemicellulose derived platform molecule xylitol (XYL) can be used as feedstock. [3] The conversion to ethylene and propylene glycol (EG and PG) involves many reaction mechanisms such as metal catalyzed dehydrogenation and hydrogenation or base promoted retroaldol splitting (Scheme 1). [4][5][6][7] Glycerol (GLY) is formed in significant amounts as by-product as well as the side product lactic acid (LA).…”

Section: Introductionmentioning

confidence: 99%

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Ru on N‐doped Carbon for the Selective Hydrogenolysis of Sugars and Sugar Alcohols

et al. 2022

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Glycols are accessible via metal-catalyzed hydrogenolysis of sugar alcohols such as xylitol obtained from hemicellulose. Rubased catalysts are highly active but also catalyze side-reactions such as decarbonylation and deoxygenation. To achieve high selectivity, these reactions need to be suppressed. In our study, we introduce heteroatom doped carbon materials as catalyst supports providing high selectivity. Heteroatom doping with nitrogen and oxygen was achieved by treating activated carbon with HNO 3 , NH 3 and H 2 or carbonization of organic precursors.For all N-doped materials a high glycol selectivity of �80 % for sorbitol and xylitol and 44 % for xylose and glucose was reached. XPS analysis confirms the presence of different nitrogen species at the carbon surface and varying ligand effects for oxygen and nitrogen. Oxygen has an electron withdrawing effect on ruthenium and leads to a decreased activity. Nitrogen has weaker electron withdrawing properties, resulting in an enhanced selectivity.

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Catalytic Deoxygenation of Xylitol to Renewable Chemicals: Advances on Catalyst Design and Mechanistic Studies

Cited by 12 publications

References 37 publications

Hydrodeoxygenation of potential platform chemicals derived from biomass to fuels and chemicals

Hydrodeoxygenation of potential platform chemicals derived from biomass to fuels and chemicals

Synthesis of Secondary Monoalcohols from Terminal Vicinal Alcohols over Silica-Supported Rhenium-Modified Ruthenium Catalyst

Ru on N‐doped Carbon for the Selective Hydrogenolysis of Sugars and Sugar Alcohols

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