Selective C−C Hydrogenolysis of Alkylbenzenes to Methylbenzenes with Suppression of Ring Hydrogenation

Yanatake, Shin; Nakaji, Yosuke; Betchaku, Mii; Nakagawa, Yoshinao; Tamura, Masazumi; Tomishige, Keiichi

doi:10.1002/cctc.201801118

Cited by 3 publications

(3 citation statements)

References 37 publications

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“…S2 ). The strong metal–support interaction (SMSI) between Ru and CeO 2 should contribute to dispersing Ru atoms [ 32 , 33 ], and such an SMSI effect would also enhance the catalytic stability (see detailed discussion in catalysis part).…”

Section: Resultsmentioning

confidence: 99%

Site-Selective Polyolefin Hydrogenolysis on Atomic Ru for Methanation Suppression and Liquid Fuel Production

Chu

Wang

et al. 2023

Research

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Catalytic hydrogenolysis of end-of-life polyolefins can produce value-added liquid fuels and therefore holds great promises in plastic waste reuse and environmental remediation. The major challenge limiting the recycling economic benefit is the severe methanation (usually >20%) induced by terminal C–C cleavage and fragmentation in polyolefin chains. Here, we overcome this challenge by demonstrating that Ru single-atom catalyst can effectively suppress methanation by inhibiting terminal C–C cleavage and preventing chain fragmentation that typically occurs on multi-Ru sites. The Ru single-atom catalyst supported on CeO 2 shows an ultralow CH 4 yield of 2.2% and a liquid fuel yield of over 94.5% with a production rate of 314.93 g fuels g Ru −1 h −1 at 250 °C for 6 h. Such remarkable catalytic activity and selectivity of Ru single-atom catalyst in polyolefin hydrogenolysis offer immense opportunities for plastic upcycling.

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Section: Resultsmentioning

confidence: 99%

Site-Selective Polyolefin Hydrogenolysis on Atomic Ru for Methanation Suppression and Liquid Fuel Production

Chu

Wang

et al. 2023

Research

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“…44 Toluene was a usual product of styrene reaction under all reaction conditions A–D (lines 6–11, Table 2; lines 1–3, Table 3). This product of a one-carbon chain-shortened initial molecule is not an experimental artefact, but a conventional product co-produced from ethylbenzene by hydrogenolysis of its CH 2 –CH 3 bond (Scheme 2), for example under catalysis by Ru/CeO 2 at 260 °C 45 or Ni/SiO 2 at 165 °C. 46 Thus, at 350 °C in alcohol, toluene was a normal by-product of olefinic CC transfer hydrogenation of styrene to ethylbenzene followed by transfer hydrogenolysis of the C(sp 3 )–C(sp 3 ) bond of its ethyl substituent.…”

Section: Resultsmentioning

confidence: 99%

Structure-guided insights into non-catalytic (α-hydroxy)alkylation of olefins with alcohols

Chibiryaev

2022

New J. Chem.

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“…This Ru/CeO 2 catalyzes regioselective hydrogenolysis of squalane, , and the regioselectivity to C secondary –C secondary bonds above C tertiary –C secondary or C tertiary –C primary bonds is higher than that of Ru/CeO 2 and Ru/SiO 2 with larger Ru metal particles. The highly dispersed Ru/CeO 2 also catalyzes regioselective hydrogenolysis of hydrogenated botryococcene, selective hydrogenolysis of alkylbenzenes to methylbenzenes, and selective hydrogenation of amide to alcohols . As related catalysts, Ru–MO x /SiO 2 (M: metal) catalysts were also tested for regioselectivity of squalane .…”

Section: Introductionmentioning

confidence: 99%

Mechanism of Formation of Highly Dispersed Metallic Ruthenium Particles on Ceria Support by Heating and Reduction

et al. 2019

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The structural change of Ru/CeO 2 and Ru/SiO 2 catalysts during pretreatments was investigated by in situ Ru K edge quick-scanning X-ray absorption fine structure (XAFS) combined with temperature-programmed reduction with H 2 and X-ray diffraction (XRD). After impregnation and drying, two pretreatment sequences were applied: (i) calcination in air at 573 K and reduction with H 2 and (ii) heating in inert gas at 573 K and reduction with H 2 . In sequence (i) of Ru/CeO 2 , the extended XAFS (EXAFS) spectra showed the formation of crystalline RuO 2 during calcination. On the other hand, in sequence (ii) of Ru/CeO 2 and Ru/SiO 2 , the EXAFS results indicated that the Ru oxide was still noncrystalline after heating. The size of Ru metal particle during reduction was determined by Ru−Ru coordination number in EXAFS (CN Ru−Ru ) and reduction degree. The size was almost constant for Ru/CeO 2 (CN Ru−Ru : about 4) or Ru/SiO 2 (CN Ru−Ru : about 8) in sequence (ii), indicating the absence of aggregation. The size was increased for Ru/CeO 2 in sequence (i); however, the XRD results suggested that each RuO 2 crystallite was slowly reduced to one Ru particle. After all, aggregation during reduction was not significant for all Ru/ CeO 2 and Ru/SiO 2 catalysts.

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Selective C−C Hydrogenolysis of Alkylbenzenes to Methylbenzenes with Suppression of Ring Hydrogenation

Cited by 3 publications

References 37 publications

Site-Selective Polyolefin Hydrogenolysis on Atomic Ru for Methanation Suppression and Liquid Fuel Production

Site-Selective Polyolefin Hydrogenolysis on Atomic Ru for Methanation Suppression and Liquid Fuel Production

Structure-guided insights into non-catalytic (α-hydroxy)alkylation of olefins with alcohols

Mechanism of Formation of Highly Dispersed Metallic Ruthenium Particles on Ceria Support by Heating and Reduction

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