Assessing C3–C4 alcohol synthesis pathways over a MgAl oxide supported K/MoS2 catalyst via 13C2-ethanol and 13C2-ethylene co-feeds

Claure, Micaela Taborga; Lee, Li-Chen; Goh, Jin Wai; Gelbaum, Leslie T.; Agrawal, Pradeep; Jones, Christopher W.

doi:10.1016/j.molcata.2016.06.025

Cited by 7 publications

(4 citation statements)

References 41 publications

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“…Therefore, only a handful of catalysts that realize the catalytic Guerbet reaction of ethanol have been developed. Heterogeneous catalytic systems generally require harsh reaction conditions and/or suffer from low selectivity . In contrast, well-defined homogeneous catalysts based on precious metals (Ru and Ir) show higher reactivity and selectivity for this transformation under milder conditions (Figure ).…”

Section: Introductionmentioning

confidence: 99%

Manganese-Catalyzed Upgrading of Ethanol into 1-Butanol

et al. 2017

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Biomass-derived ethanol is an important renewable feedstock. Its conversion into high-quality biofuels is a promising route to replace fossil resources. Herein, an efficient manganese-catalyzed Guerbet-type condensation reaction of ethanol to form 1-butanol was explored. This is the first example of upgrading ethanol into higher alcohols using a homogeneous non-noble-metal catalyst. This process proceeded selectively in the presence of a well-defined manganese pincer complex at the parts per million (ppm) level. The developed reaction represents a sustainable synthesis of 1-butanol with excellent turnover number (>110 000) and turnover frequency (>3000 h). Moreover, mechanistic studies including control experiments, NMR spectroscopy, and X-ray crystallography identified the essential role of the "N-H moiety" of the manganese catalysts and the major reaction intermediates related to the catalytic cycle.

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Section: Introductionmentioning

confidence: 99%

Manganese-Catalyzed Upgrading of Ethanol into 1-Butanol

et al. 2017

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“…This implies that the direct coupling of C 2 fragments is a probable source of additional C 4+ alcohols and hydrocarbons. Previous studies 13,35 on ethanol conversion using 13 C have shown that the coupling of C 2 fragments is involved in the formation of butanol (see in Table 3).…”

Section: Nsmentioning

confidence: 99%

“…Only small amounts of DEE were observed, which is a major product of ethanol conversion on a Bronsted acid catalyst. 35 This suggests that even in the absence of potassium, ethanol conversion, including dehydrations, proceeds on the Lewis acid sites of the sulfide catalyst, which are likely associated with CUS.…”

Section: Nsmentioning

confidence: 99%

A Study of the Effects of K-Modification and (Co, Ni, Fe)-Promotion on a Supported MoS₂-Based Catalyst for Ethanol Conversion

Dipheko,

Osman,

Permyakov

et al. 2024

J. Phys. Chem. C

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K-(Me)MoS 2 catalysts (Me = Co, Fe, Ni) supported on activated carbon were synthesized via the incipient wetness impregnation method. The catalysts were characterized using low-temperature N 2 -adsorption, SEM-EDX, XRD, and TEM. The catalysts were evaluated in an ethanol conversion reaction using a fixed-bed reactor to investigate the influence of catalytic active phase composition on the yields of various products. It had been found that K and Co(Ni, Fe) incorporation contributed to the significant changes in catalytic behavior of sulfide catalysts. The addition of K resulted in partial poisoning of the active sites, resulting in a decrease in catalytic activity when compared to the reference MoS 2 /AG-3 and (Me)MoS 2 /AG-3 catalysts. Conversion decreased as follows: FeMoS 2 > MoS 2 ≥ NiMoS 2 > CoMoS 2 > K-CoMoS 2 > K-NiMoS 2 > K-MoS 2 > KFeMoS 2 . K-addition into (Me)MoS 2 /AG-3 increased the yield of alcohol at the expense of acetate and hydrocarbons. It reduced the probability of C−O bond breaking in the adsorbed intermediate and altered selectivity away from alkyl fragment toward alkoxide fragment formation. This allowed us to suppose that K somewhat promotes sites responsible for higher alcohol synthesis. Catalysts free of K were shown to be more advantageous for the synthesis of ethyl acetate, resulting in high yields, particularly with the use of MoS 2 /AG-3 and CoMoS 2 / AG-3 catalysts.

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“…Two chemical ways are worthy of note: a selective two-step approach coupling the formation of propylene via a standard MTO technology with hydroformylation/hydrogenation steps according to the alcohols OXO synthesis − and a more challenging, rather unselective, route with the direct use of syngas to generate either methanol selectively or a broader range of so-called “higher” alcohols (HAS route). Among the numerous catalytic systems developed over the years, four main classes are noteworthy, being the focus of many valuable reviews: − Rhodium-based catalysts producing mainly ethanol, − modified FT catalysts based on cobalt and, to a lesser extent, iron, , MoS 2 /MoC-based catalysts, − and optimized high- and low temperatures methanol catalysts based either on ZnO/Cr 2 O 3 or on the Cu/ZnO/Al 2 O 3 system often modified with alkali promoters (e.g., Cs and K). − Although many of these four catalytic approaches have been further developed, some tested in pilot plants and/or patented, no large-scale industrial implementation has been so far reported. This might be explained by enduring problems associated with the stability of the catalysts, the exothermic character of the synthesis, and the moderate selectivity of the synthesis resulting in a broader product range (e.g., linear vs branched alcohol issue, oligomerization, etc.).…”

Section: Catalytic Chemical Route From Synthesis Gas To C4 Moleculesmentioning

confidence: 99%

The Complex Way to Sustainability: Petroleum-Based Processes versus Biosynthetic Pathways in the Formation of C4 Chemicals from Syngas

Stoll

Boukis

Neumann

et al. 2019

Ind. Eng. Chem. Res.

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The environmental impact of the increasing anthropogenic CO2 emissions and the depletion of essential resources, once subjects of concern only for a minority of specialists, are now in the focus of many institutions and are de facto top priorities in many agendas. The ensuing environmental regulations, improved safety requirements, and growing critical public view on the chemical industry are the main reasons for an intense search for alternative synthetic routes to commodity chemicals and specialty chemicals. The skillful utilization of waste biomass, an inexhaustible resource, is revealed to be an important tool for a balanced CO2 management and the way to promising feedstock for many chemical and biochemical syntheses. The scope of the present contribution is to outline the main differences between chemical and biotechnological synthesis routes starting from waste biomass, focusing on C4-chemicals as an exemplary case study.

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Assessing C3–C4 alcohol synthesis pathways over a MgAl oxide supported K/MoS2 catalyst via 13C2-ethanol and 13C2-ethylene co-feeds

Cited by 7 publications

References 41 publications

Manganese-Catalyzed Upgrading of Ethanol into 1-Butanol

Manganese-Catalyzed Upgrading of Ethanol into 1-Butanol

A Study of the Effects of K-Modification and (Co, Ni, Fe)-Promotion on a Supported MoS₂-Based Catalyst for Ethanol Conversion

The Complex Way to Sustainability: Petroleum-Based Processes versus Biosynthetic Pathways in the Formation of C4 Chemicals from Syngas

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Assessing C3–C4 alcohol synthesis pathways over a MgAl oxide supported K/MoS2 catalyst via 13C2-ethanol and 13C2-ethylene co-feeds

Cited by 7 publications

References 41 publications

Manganese-Catalyzed Upgrading of Ethanol into 1-Butanol

Manganese-Catalyzed Upgrading of Ethanol into 1-Butanol

A Study of the Effects of K-Modification and (Co, Ni, Fe)-Promotion on a Supported MoS2-Based Catalyst for Ethanol Conversion

The Complex Way to Sustainability: Petroleum-Based Processes versus Biosynthetic Pathways in the Formation of C4 Chemicals from Syngas

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A Study of the Effects of K-Modification and (Co, Ni, Fe)-Promotion on a Supported MoS₂-Based Catalyst for Ethanol Conversion