Catalytic functionalities of nano Ru catalysts supported on TiO2–ZrO2 mixed oxide for vapor phase hydrogenolysis of glycerol to propanediols

Kumar, V. Pavan; Beltramini, Jorge; Samudrala, Shanthi Priya; Srikanth, Amirineni; Bhanuchander, Ponnala; Chary, Komandur V. R.

doi:10.1007/s13203-015-0136-8

Cited by 11 publications

(16 citation statements)

References 36 publications

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“…The acidity and type of active sites for various Ru/CNT catalysts reported in the literature varies considerably and is known to be a function of the preparation procedure (e.g., acid pre-treatment conditions) [39,40]. Weak and medium acid sites were observed for the Ru/ZrO2 catalyst with two desorption peaks below 400 °C ( Figure S1), in line with literature data [41,42]. For Ru/SiO2 and Ru/Al2O3, all three types of acid sites are present.…”

Section: Catalyst Characterizationsupporting

confidence: 85%

Support Screening Studies on the Hydrogenation of Levulinic Acid to γ-Valerolactone in Water Using Ru Catalysts

et al. 2016

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γ-Valerolactone (GVL) has been identified as a sustainable platform chemical for the production of carbon-based chemicals. Here we report a screening study on the hydrogenation of levulinic acid (LA) to GVL in water using a wide range of ruthenium supported catalysts in a batch set-up (1 wt. % Ru, 90 • C, 45 bar of H 2 , 2 wt. % catalyst on LA). Eight monometallic catalysts were tested on carbon based(C, carbon nanotubes (CNT)) and inorganic supports (Al 2 O 3 , SiO 2 , TiO 2 , ZrO 2 , Nb 2 O 5 and Beta-12.5). The best result was found for Ru/Beta-12.5 with almost quantitative LA conversion (94%) and 66% of GVL yield after 2 h reaction. The remaining product was 4-hydroxypentanoic acid (4-HPA). Catalytic activity for a bimetallic RuPd/TiO 2 catalyst was by far lower than for the monometallic Ru catalyst (9% conversion after 2 h). The effects of relevant catalyst properties (average Ru nanoparticle size, Brunauer-Emmett-Teller (BET) surface area, micropore area and total acidity) on catalyst activity were assessed.

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Section: Catalyst Characterizationsupporting

confidence: 85%

Support Screening Studies on the Hydrogenation of Levulinic Acid to γ-Valerolactone in Water Using Ru Catalysts

et al. 2016

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“…The crystallization of Ru particles was reported to be responsible for the reduction peak of Ru oxides. The reduction peak at lower temperature was attributed to the reduction of well-dispersed RuO x particles, while the reduction peak at higher temperature corresponded to the reduction of RuO x with larger particle size 23 , 24 , 32 . On the other hand, the Ru/TiO 2 -A and Ru/TiO 2 -sol showed only single sharp reduction peak, suggesting to the homogeneity in particle size distribution of Ru species.…”

Section: Resultsmentioning

confidence: 98%

“…All the Ru-based catalysts showed three main reduction peaks consisting of the first reduction peak at 100–250 °C corresponding to the reduction of Ru oxides to Ru 0 metal 27 – 29 , the reduction peak in the range of 300–450 °C corresponding to Ru interacting with TiO 2 support in the form of Ru-TiO x sites 27 – 30 , and the broad reduction peak at 570–730 °C assigning to the reduction of surface capping oxygen of TiO 2 support (partial reduction of TiO 2 ). Considering the reduction peak of Ru oxides to Ru 0 metal, a series of multiple reducible peaks of the Ru oxides reduction were observed on the Ru/TiO 2 -P25 and Ru/TiO 2 -R catalysts probably due to the presence of different Ru ion species and/or different Ru particle sizes in different environments on the surface of the support 23 , 30 , 31 . The crystallization of Ru particles was reported to be responsible for the reduction peak of Ru oxides.…”

Section: Resultsmentioning

confidence: 99%

“…The metal dispersion of the catalysts was evaluated by CO pulse chemisorption using a Micromeritics ChemiSorb 2750 pulse chemisorption system. The stoichiometry of CO chemisorption was CO/Ru = 1 23 . Prior to chemisorption, the catalyst was reduced under H 2 (25 cm 3 /min) at 300 °C for 2 h. Afterwards, the sample was maintained at 300 °C under helium flow (25 cm 3 /min) for 0.5 h for removing the physical adsorption of H 2 .…”

Section: Methodsmentioning

confidence: 99%

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Effects of TiO2 structure and Co addition as a second metal on Ru-based catalysts supported on TiO2 for selective hydrogenation of furfural to FA

Tolek

Nanthasanti

Pongthawornsakun

et al. 2021

Sci Rep

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The TiO2 supported Ru-based catalysts were prepared with 1.5 wt% Ru and 0–0.8 wt% Co on various TiO2 (anatase, rutile, P-25, and sol–gel TiO2) and studied in the liquid-phase selective hydrogenation of furfural to furfuryl alcohol (FA) under mild conditions (50 °C and 2 MPa H2). The presence of high anatase crystallographic composition on TiO2 support was favorable for enhancing hydrogenation activity, while the strong interaction between Ru and TiO2 (Ru–TiOx sites) was required for promoting the selectivity to FA. The catalytic performances of bimetallic Ru–Co catalysts were improved with increasing Co loading due to the synergistic effect of Ru–Co alloying system together with the strong interaction between Ru and Co as revealed by XPS, H2-TPR, and TEM–EDX results. The enhancement of reducibility of Co oxides in the bimetallic Ru–Co catalysts led to higher hydrogenation activity with the Ru–0.6Co/TiO2 catalyst exhibited the best performances in FA selective hydrogenation of furfural to FA under the reaction conditions used.

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“…In this vain, several glycerol valorization processes such as esterification [1], carbonylation [11,12], etherification [13], hydrogenolysis [14][15][16], acetylation dehydration, oligomerization, dehydrogenation, and glycerol reforming [5,17] have been proposed. Among all of these processes, upgrading glycerol by catalytic acetylation has received tremendous research attention, because it produces commercially valuable esters, namely, mono acetin (MAG), di acetin (DAG), and tri acetin (TAG) [4,7].…”

Section: Introductionmentioning

confidence: 99%

Untitled

2018

PPS

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Growing global biodiesel production demands valorization of bio-glycerol derived from biodiesel, which is crucial to make bio refinery process economical. Hence, a series of H 2 SO 4 modified sulfonated Montmorillonite K10 catalysts were synthesized, characterized and evaluated for acetylation of bio-glycerol with acetic acid to produce mono acetin (MAG), di acetin (DAG), tri acetin (TAG) and di-glycerol tri-acetate (DGTA), which are the oxygenated fuel additives and facilitate the economic viability of biodiesel production so the bio refinery. The synthesized catalysts were characterized by compressive suite of characterization techniques such as powder X-ray diffraction (XRD), low temperature N 2 physisorption, temperature programmed ammonia desorption (TPAD) and Fourier transform infrared (FTIR). The glycerol conversion and product distribution results were found to correlate with the acidity and textural properties of the catalyst. 20% (w/w) SO 4 /K10 was revealed to be a promising catalyst for glycerol acetylation with 99% glycerol conversion and with respective yield towards MAG, DAG, TGA and DGTA of 23%, 59%, 15%, and 2%. Moreover, 20% (w/w) SO 4 /K10 catalyst was found to maintain the stable catalytic activity for three reaction cycles. However, the partial catalyst deactivation was observed after third reaction cycle, partly due to deposition of coke and loss of active sites during the reaction.

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Catalytic functionalities of nano Ru catalysts supported on TiO2–ZrO2 mixed oxide for vapor phase hydrogenolysis of glycerol to propanediols

Cited by 11 publications

References 36 publications

Support Screening Studies on the Hydrogenation of Levulinic Acid to γ-Valerolactone in Water Using Ru Catalysts

Support Screening Studies on the Hydrogenation of Levulinic Acid to γ-Valerolactone in Water Using Ru Catalysts

Effects of TiO2 structure and Co addition as a second metal on Ru-based catalysts supported on TiO2 for selective hydrogenation of furfural to FA

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