Regulating Aromatic Alcohols Distributions by Cofeeding Methanol with Ethanol over Cobalt‐Hydroxyapatite Catalyst

Zhou, Bai-Chuan; Wang, Qing‐Nan; Weng, Xuefei; He, Lei; Li, Wen-Cui Prof.; Lu, An‐Hui

doi:10.1002/cctc.202000010

Cited by 9 publications

(9 citation statements)

References 43 publications

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“…The synthesis of aromatic aldehydes from low-carbon aliphatic aldehydes (n ≤ 6) was explored under the optimal conditions ( Figure 5 ). When formaldehyde or acrolein were co-fed with acetaldehyde, a 10–12% selectivity of benzaldehyde was obtained, which was attributed to the complex network of competing reactions in these coupling-aromatization processes, leading to broad product distributions ( Zhou et al., 2020 ). Interestingly, p -MBA could be selectively synthesized from acetaldehyde or 2-butenal.…”

Section: Resultsmentioning

confidence: 99%

Direct synthesis of p-methyl benzaldehyde from acetaldehyde via an organic amine-catalyzed dehydrogenation mechanism

et al. 2021

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Summary p -Methyl benzaldehyde ( p -MBA) is a class of key chemical intermediates of pharmaceuticals. Conventional industrial processes for p -MBA production involve the consecutive photochlorination, amination, and acid hydrolysis of petroleum-derived p -xylene, while producing vast pollutants and waste water. Herein, we report a direct, green route for selective synthesis of p -MBA from acetaldehyde using a diphenyl prolinol trimethylsilyl ether catalyst. The optimized p -MBA selectivity is up to 90% at an acetaldehyde conversion as high as 99.8%. Intermediate structure and 18 O-isotope data revealed that the conversion of acetaldehyde to p -methylcyclohexadienal intermediates proceeds in an enamine-iminium intermediate mechanism. Then, controlled experiments and D-isotope results indicated that the dehydrogenation of p -methylcyclohexadienal to p -MBA and H 2 is catalyzed by the same amines through an iminium intermediate. This is an example that metal-free amines catalyze the dehydrogenation (releasing H 2 ), rather than using metals or stoichiometric oxidants.

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Section: Resultsmentioning

confidence: 99%

Direct synthesis of p-methyl benzaldehyde from acetaldehyde via an organic amine-catalyzed dehydrogenation mechanism

et al. 2021

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“…Notably, benzyl alcohol (BA−OH) is selectively formed on Co−HAP by co-feeding methanol with ethanol, and its selectivity increases with the partial pressure of methanol. 60 A maximum benzyl alcohol selectivity of ∼30% was achieved in the feed of 4 kPa methanol and 2 kPa ethanol at 325 °C. Detailed kinetic measurement indicates that high methanol pressure favors the formation of benzaldehyde and benzyl alcohols by facilitating the formation of enal intermediates with an odd carbon number.…”

Section: Aromatization To Aromatic Alcohols/aldehydesmentioning

confidence: 99%

Catalytic Conversion of Ethanol to Oxygen-Containing Value-Added Chemicals

He,

Zhou,

Sun

et al. 2023

ACS Catal.

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Ethanol, mainly produced from the yeast fermentation of biomass, is one of the most important renewable building blocks for synthesizing value-added chemicals. Different pathways of ethanol conversion, including dehydrogenation, C–C bond coupling, aromatization, hydrogen transfer, dehydration, etc., can be achieved over a variety of catalysts. In this Perspective, we focus on the catalytic one-pot ethanol conversion processes for producing oxygen-containing value-added chemicals. The details include the catalyst design strategy, selectivity manipulation, and mechanism investigation. We hope this Perspective will inspire future catalyst design for reactions by tailoring the C–H bond, C–O bond, or O–H bond and shed light on industry applications with carbon neutrality.

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“…The selectivity for aromatic oxygenates is as high as 40% over the Cu-HAP catalyst under a N 2 environment, which is in good accordance with our previous research. 30,32 Meanwhile, additional condensation products are 2-butenal, 2-butenol, and other unsaturated intermediates, resulting from acetaldehyde condensation (Table S2). 28 However, a further increase in hydrogen pressure would apparently shift the product selectivity from aromatic oxygenates to higher aliphatic alcohols, and barely any 2-MB-OH is detected when the H 2 partial pressure is above 20 kPa.…”

Section: Effect Of H 2 Partial Pressure On Productmentioning

confidence: 99%

Enhancing Ethanol Coupling to Produce Higher Alcohols by Tuning H₂ Partial Pressure over a Copper-Hydroxyapatite Catalyst

Zhou

et al. 2022

ACS Catal.

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Catalytic upgrading of ethanol, as a platform molecule from biomass to higher alcohols (C4–12), is a low-carbon route for value-added chemical production. However, the products are generally obtained in low selectivity due to the uncontrollable reactivity of intermediates that cause a complex reaction network. In this study, we show that unsaturated intermediates of aldehydes can be rapidly hydrogenated by surface hydrogen species during the ethanol upgrading process, thereby greatly inhibiting the cyclization reaction of aldehydes. Specifically, the product distributions on the Cu-hydroxyapatite (Cu-HAP) catalyst shift stepwise to higher alcohols from aromatic oxygenates with the partial pressure of hydrogen increasing from 0 to 95 kPa. Kinetic measurements and in situ ethanol infrared results indicated that the intermediates during this process are acetaldehyde and 2-butenal. Combined with physical structure and chemical state analysis of the catalyst, we found that Cu sites catalyze the hydrogenation of the CC bond of 2-butenal under a hydrogen atmosphere. The C–C coupling of ethanol to higher alcohols over Cu-HAP follows the Guerbet mechanism. In comparison, on bare HAP, n-butanol is formed as a primary product even though little amount of acetaldehyde was detected, indicating that ethanol proceeds mainly in a direct coupling process to yield higher alcohols. This study introduces an efficient ethanol valorization approach that is enabled by subtle control of the intermediate conversion over the Cu-HAP catalyst by the hydrogen partial pressure.

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Regulating Aromatic Alcohols Distributions by Cofeeding Methanol with Ethanol over Cobalt‐Hydroxyapatite Catalyst

Cited by 9 publications

References 43 publications

Direct synthesis of p-methyl benzaldehyde from acetaldehyde via an organic amine-catalyzed dehydrogenation mechanism

Direct synthesis of p-methyl benzaldehyde from acetaldehyde via an organic amine-catalyzed dehydrogenation mechanism

Catalytic Conversion of Ethanol to Oxygen-Containing Value-Added Chemicals

Enhancing Ethanol Coupling to Produce Higher Alcohols by Tuning H₂ Partial Pressure over a Copper-Hydroxyapatite Catalyst

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Regulating Aromatic Alcohols Distributions by Cofeeding Methanol with Ethanol over Cobalt‐Hydroxyapatite Catalyst

Cited by 9 publications

References 43 publications

Direct synthesis of p-methyl benzaldehyde from acetaldehyde via an organic amine-catalyzed dehydrogenation mechanism

Direct synthesis of p-methyl benzaldehyde from acetaldehyde via an organic amine-catalyzed dehydrogenation mechanism

Catalytic Conversion of Ethanol to Oxygen-Containing Value-Added Chemicals

Enhancing Ethanol Coupling to Produce Higher Alcohols by Tuning H2 Partial Pressure over a Copper-Hydroxyapatite Catalyst

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Enhancing Ethanol Coupling to Produce Higher Alcohols by Tuning H₂ Partial Pressure over a Copper-Hydroxyapatite Catalyst