Hemicellulose arabinogalactan hydrolytic hydrogenation over Ru-modified H-USY zeolites

Murzin, Dmitry Yu.; Kusema, Bright T.; Murzina, Elena V.; Aho, Atte; Tokarev, A. V.; Boymirzaev, Azamat; Wärnå, Johan; Dapsens, Pierre Y.; Mondelli, Cecilia; Pérez‐Ramírez, Javier; Salmi, Tapio

doi:10.1016/j.jcat.2015.06.022

Cited by 34 publications

(14 citation statements)

References 43 publications

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“…The NH 3 ‐TPD profiles in Figure B reveal more than two peaks for the catalysts at temperatures of 495 K and higher, indicating the presence of complex acid types with different acid strengths. As the gallium content increased, the lower NH 3 desorption peak shifted to an even lower temperature, suggesting a decrease in the acid strength of the weak acid sites . However, the other NH 3 desorption peak shifted to higher temperatures, suggesting an increase in the acid strength of the stronger acid sites.…”

Section: Resultsmentioning

confidence: 93%

“…As the gallium content increased, the lower NH 3 desorption peak shifted to an even lower temperature, suggesting ad ecrease in the acid strength of the weak acid sites. [39] However,t he other NH 3 desorption peak shifted to higher temperatures, suggesting an increase in the acid strength of the stronger acid sites. These results are similar to the observations of Meng et al [40] over Y/ASA composites.…”

Section: Aciditypropertiesmentioning

confidence: 96%

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Gallium Modified HUSY Zeolite as an Effective Co‐support for NiMo Hydrodesulfurization Catalyst and the Catalyst's High Isomerization Selectivity

Zhou

Wei

et al. 2017

Chemistry A European J

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The effects of metal-modified acidic co-supports on the hydrodesulfurization (HDS) activity and isomerization selectivity of highly refractory organosulfur compounds such as 4,6-dimethyldibenzothiophene have been investigated. Y zeolite crystals with high Si/Al ratios and small crystallite sizes were successfully synthesized by a new hydrothermal synthesis approach. The synthesized Y zeolite crystals were ion-exchanged and stabilized. The prepared samples were then modified with different gallium contents using an impregnation method to adjust their acidity properties, and these modified samples were used as co-supports for NiMo sulfide HDS catalysts. The catalyst containing 10 wt.% zeolite Y modified by 2 wt.% gallium (NiMo/2GaY-ASA-A) exhibited the highest HDS activity, with 4,6-dimethyldibenzothiophene (4,6-DMDBT) conversion nearly double the rate of the catalyst without zeolite at 563 K, 4.0 MPa and liquid hourly space velocity (LHSV) of 40 h . NiMo/2GaY-ASA-A also exhibited superior isomerization ability, with 3,4'-DMBP, 4,4'DMBP, and 3,6-DMDBT as the main products, indicating that the isomerization pathway was the main reaction route over NiMo/2GaY-ASA-A. The superior catalytic performance is related to the synergistic effect of the proper amount of medium and strong Brønsted acid sites. The compounds 3,6-DMDBT and 3,7-DMDBT (isomers of 4,6-DMDBT) and 3,4,6-TMDBT and tetra-methyl-DBT (transmethyl products) were detected simultaneously in the HDS product of 4,6-DMDBT for the first time over NiMo/GaY-ASA-A catalysts. Finally, a new reaction network over NiMo/2GaY-ASA-A was proposed.

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Section: Resultsmentioning

confidence: 93%

Section: Aciditypropertiesmentioning

confidence: 96%

Gallium Modified HUSY Zeolite as an Effective Co‐support for NiMo Hydrodesulfurization Catalyst and the Catalyst's High Isomerization Selectivity

Zhou

Wei

et al. 2017

Chemistry A European J

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“…As shown in Scheme a, arabinogalactan (arabinoxylan) is first hydrolyzed to give arabinose and galactose (xylose and arabinose) in water over acid sites followed by being hydrogenized to yield arabitol and galactitol (xylitol and arabitol) in the presence of metal species . Ru (5 wt %)/USY‐15, which was prepared by the incorporation of Ru into USY zeolite through spray deposition, was developed for the hydrolytic hydrogenation of arabinogalactan in water and afforded 23 % yield of alditols in the presence of 2 MPa H 2 at 185 °C within 4 h . Dehydration side products (e.g., furfural and HMF) were also generated over different Ru/USY‐15 catalysts (i.e., Ru (1 wt %)/USY‐15, Ru (2.5 wt %)/USY‐15 and Ru (5 wt %)/USY‐15), owing to the presence of Brønsted acidity in USY‐15 zeolite, but an increase in the metal loading (i.e., Ru(5 wt %)/USY‐15) could suppress dehydration side reactions associated with sugar dehydration and thereby improve the yield of alditols .…”

Section: Catalytic Processes With a Decrease In Carbon Numbermentioning

confidence: 99%

“…Ru (5 wt %)/USY‐15, which was prepared by the incorporation of Ru into USY zeolite through spray deposition, was developed for the hydrolytic hydrogenation of arabinogalactan in water and afforded 23 % yield of alditols in the presence of 2 MPa H 2 at 185 °C within 4 h . Dehydration side products (e.g., furfural and HMF) were also generated over different Ru/USY‐15 catalysts (i.e., Ru (1 wt %)/USY‐15, Ru (2.5 wt %)/USY‐15 and Ru (5 wt %)/USY‐15), owing to the presence of Brønsted acidity in USY‐15 zeolite, but an increase in the metal loading (i.e., Ru(5 wt %)/USY‐15) could suppress dehydration side reactions associated with sugar dehydration and thereby improve the yield of alditols . Analogously, acid–metal bifunctionalized Ru/USY, which was fabricated through an ion‐exchange method, accomplished highly effective conversion of arabinoxylan into pentitols (xylitol+arabitol), giving a total yield of pentitols of up to 90 mol % over 5 MPa H 2 at 160 °C after 5 h .…”

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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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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“…A process of hydrolytic hydrogenation of arabinogalactan from hemicellulose into 5-hydroxymethylfurfural and furfural in the presence of a modified Ru-USY zeolite (Si/Al = 15 and 30, 1-5% ruthenium) has also been developed [56]. Another example is the usage of H-ZSM-5 zeolite in the dehydration of xylose to furfural.…”

Section: -Hydroxymethylfurfural and Furfuralmentioning

confidence: 99%

Concepts of modern technologies of obtaining valuable biomass-derived chemicals

2018

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Hemicellulose arabinogalactan hydrolytic hydrogenation over Ru-modified H-USY zeolites

Cited by 34 publications

References 43 publications

Gallium Modified HUSY Zeolite as an Effective Co‐support for NiMo Hydrodesulfurization Catalyst and the Catalyst's High Isomerization Selectivity

Gallium Modified HUSY Zeolite as an Effective Co‐support for NiMo Hydrodesulfurization Catalyst and the Catalyst's High Isomerization Selectivity

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

Concepts of modern technologies of obtaining valuable biomass-derived chemicals

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