The mission of addition and fission – catalytic functionalization of oleochemicals

Seidensticker, Thomas; Vorholt, Andreas J.; Behr, Arno

doi:10.1002/ejlt.201500190

Cited by 32 publications

(21 citation statements)

References 138 publications

(165 reference statements)

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“…Their general chemical structure consisting of a long linear alkyl chain and additional functional groups makes these particularly interesting for polycondensates . Furthermore, a major part of these types of substrates is unsaturated and offers potential for further functionalization, which in principle makes linear bifunctional molecules easily accessible. Especially promising in the context of green chemistry are sustainable concepts, which allow for the direct use of commodity oleo chemicals in atom‐economic transition‐metal‐catalyzed reactions, as shown, for example, in isomerizing methoxycarbonylation…”

Section: Methodsmentioning

confidence: 99%

From Oleo Chemicals to Polymer: Bis‐hydroaminomethylation as a Tool for the Preparation of a Synthetic Polymer from Renewables

et al. 2016

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Resource‐efficient bis‐hydroaminomethylation of the castor oil derived renewables methyl 10‐undecenoate and 10‐undecene‐1‐ol with piperazine furnished linear, bifunctional molecules. A structured and sustainable path towards a novel polyester from these monomers was developed. Key to success was the selective crystallization of the linear product directly from the crude reaction mixture in >98 % purity. Additionally, with this methodology, the homogeneous Rh catalyst was retained in the supernatant and was successfully recycled. Finally, polycondensation yielded a novel piperazine‐linked polyester.

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Section: Methodsmentioning

confidence: 99%

From Oleo Chemicals to Polymer: Bis‐hydroaminomethylation as a Tool for the Preparation of a Synthetic Polymer from Renewables

et al. 2016

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“…Ethenolysis, that involves the cross‐metathesis reaction between ethylene and another olefin, has recently emerged as a powerful methodology for the production of α ‐olefins and in particular the catalytic upgrading of biomass‐derived feedstocks, e. g ., the conversion of long‐chain esters such as oleates to the corresponding terminal olefins . The research focus has revolved around oleates and related esters owing to their abundance in vegetable oils and the high value of terminal olefins produced from those substrates and ethylene.…”

Section: Introductionmentioning

confidence: 99%

Acrylate Esters by Ethenolysis of Maleate Esters with Ru Metathesis Catalysts: an HTE and a Technoeconomic Study

Engl

Tsygankov

Silva

et al. 2020

Helvetica Chimica Acta

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Switzerland e Current address: A.N. Nesmeyanov Institute of Organoelement Compounds of the Russian Academy of Sciences, Vavilova str. 28, RU-119991 Moscow, RussiaDedicated to our colleague, friend and mentor Prof. Peter Chen on the occasion of his 60th birthday A high throughput experimentation (HTE) study identified active Ru metathesis catalysts and reaction conditions for the ethenolysis of maleate esters to the respective acrylate esters. Catalysts were tested at various loadings (75-10'000 ppm) and temperatures (30-60°C) with maleate esters dissolved in toluene (up to ca. 44 wt-%) or neat and at variable partial pressures of ethylene (0.2 -10 bar). Ruthenium catalysts containing a PCy 3 ligand, such as 1st or 2nd generation Grubbs catalysts, as well as the state-of-the-art catalysts containing cyclic alkyl amino carbene (CAAC) ligands, are generally inferior to Hoveyda-Grubbs 2nd generation catalyst in ethenolysis of maleates. Productive turnover numbers could exceed 1900 if the ethenolysis reaction is performed at low ethylene pressure (0.2 -3 bar) and reach 5200 when a polymeric phenol additive was used. Such catalytic performance falls well within the window practiced in industry. Moreover, a crude technoeconomic analysis finds similar production cost for the ethenolysis route and conventional technology, that is, propene oxidation followed by esterification, justifying research to further improve the ethenolysis route.

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“…Homogeneous catalysts possess a huge potential for functionalizing unsaturated oleochemicals, such as unsaturated fatty acids and derivatives thereof. [1][2][3] As presented in Figure 1, aldehydes are accessible by rhodium-catalysed hydroformylation, which can undergo numerous subsequent reactions, to carboxylic acids, alcohols, or amines. [4,5] Bifunctional molecules are thus formed potentially having very interesting applications as precursors for polycondensates, lulbricants, or surfactants.…”

Section: Introductionmentioning

confidence: 99%

Improving Aqueous Biphasic Hydroformylation of Unsaturated Oleochemicals Using a Jet‐Loop‐Reactor

Herrmann

Bianga

Palten

et al. 2019

Euro J Lipid Sci & Tech

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In two case studies, the reaction performance of the aqueous biphasic hydroformylation of two industrially relevant oleochemicals, namely methyl 10-undecenoate (case 1) and methyl oleate (case 2), is significantly improved by the use of a Jet-Loop Reactor concept. Based on previously reported studies, only the two green and benign co-solvents, 1-butanol and isopropanol are applied, respectively, in the absence of any additional auxiliary. Both reactions benefit highly from using this special piece of equipment, specifically designed for improving gas-liquid-liquid mixing to create large interfacial areas with no moving internals. In case 1, the loading of the co-solvent 1-butanol is successfully reduced. For the first time significant yields (>40% after 1 h) are obtained in the absence of any co-solvent, which is very beneficial, since aldehyde products and substrate form a pure product phase enabling straightforward separation. In case 2, the loading of the substrate methyl oleate is successfully increased from 6 to 30 wt% still showing satisfying productivity. At 15 wt%, the yield of the desired internal aldehydes in the jet-loop reactor is increased by a factor of five compared to a stirred tank reactor after 3 h. Practical Applications: The production of aldehydes from hydroformylation of olefins is highly relevant for the chemical industry, since these can undergo numerous subsequent reactions, to form for instance alcohols, amines, and carboxylic acids. Generally, aldehydes from oleochemicals can serve as platform chemicals for gaining access to bifunctional molecules, which are interesting as polymer precursors. Performing hydroformylation with a water-based solvent system enables efficient product separation from the aqueous catalyst phase for the realzation of more sustainable processes. By using the Jet-Loop Reactor, the performance of the reaction system can be greatly improved addressing its practical relevance.

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The mission of addition and fission – catalytic functionalization of oleochemicals

Cited by 32 publications

References 138 publications

From Oleo Chemicals to Polymer: Bis‐hydroaminomethylation as a Tool for the Preparation of a Synthetic Polymer from Renewables

From Oleo Chemicals to Polymer: Bis‐hydroaminomethylation as a Tool for the Preparation of a Synthetic Polymer from Renewables

Acrylate Esters by Ethenolysis of Maleate Esters with Ru Metathesis Catalysts: an HTE and a Technoeconomic Study

Improving Aqueous Biphasic Hydroformylation of Unsaturated Oleochemicals Using a Jet‐Loop‐Reactor

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