Hydroformylation

Zhang, Baoxin; Fuentes, Dilver Peña; Börner, Armin

doi:10.1007/s40828-021-00154-x

Cited by 28 publications

(25 citation statements)

References 83 publications

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“…In addition, the activity of two catalytic systems comprised of Ru 3 (CO) 12 and two well-known typical phosphines such as PPh 3 and Xantphos commonly used in hydroformylations (entries 2 and 3, Table 1), were compared with that of 0.5RuÀ Ch@SiO 2 . [50] We obtained that the influence of both phosphines on the catalytic performance of Ru 3 (CO) 12 was of the same order as with separately added Ch@SiO 2 (entry 6, Table 1) and markedly lower than that of the as-prepared 0.5RuÀ Ch@SiO 2 catalyst (entry 7, Table 1).…”

Section: Chemcatchemmentioning

confidence: 79%

Chitosan‐Silica as a Cheap Carrier and Green Soft Ligand for Improved Ru‐catalyzed Hydroformylation

et al. 2022

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Dodecacarbonyltriruthenium Ru3(CO)12 has been immobilized onto a biopolymer (chitosan) supported on SiO2 (Ch@SiO2) to give Ru−Ch@SiO2. Ch@SiO2 behaves as a soft, recoverable and bulky ligand allowing the stabilization of released Ru active species and preventing its irreversible reduction to Ru0. Under these conditions very high activity (TOF= 1086 h−1; TON=2749) and regioselectivity (n:iso=92 : 8) are obtained, surpassing that of the homogeneous Ru3(CO)12 counterpart. Spectroscopic studies have shown that Ru3(CO)12 transforms into a mononuclear Run+ (n=2,3) di o try carbonyl species by interacting with the amido/amino groups of the biopolymer, being released into the reaction media whilst stabilized by the chitosan functional groups. The herein 0.5 Ru‐Ch@SiO2 catalyst can operate be operated under a semi‐continuous mode for at least 14 h without deactivation, representing providing a starting point in the search for a green catalyst with definitive industrial application in hydroformylations. In particular in the search for a heterogeneous catalyst away from the use of phosphines and their known drawbacks (i. e. tedious synthesis, facile oxidation of phosphor center, ..) as well as expensive Rh as active site.

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Section: Chemcatchemmentioning

confidence: 79%

Chitosan‐Silica as a Cheap Carrier and Green Soft Ligand for Improved Ru‐catalyzed Hydroformylation

et al. 2022

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“…With hydroformylation kinetics generally having a negative order in CO due to competitive binding, [32–34] the use of electron‐withdrawing phosphite ligands that facilitate CO dissociation from the metal lead to increased reaction rates compared to electron‐donating ligands such as phosphines [3] . Phosphites also tend to be more stable towards aerobic oxidation than the more electron‐rich phosphines but often suffer from hydrolysis, which can be diminished by the incorporation of bulky groups in the organic backbone close to the P−O bond [3,5] . The use of sterically demanding substituents has the additional advantages of enhancing catalyst activity, as there is less space for more ligands to coordinate to Rh which allows the hydroformylation of less reactive olefins [35] .…”

Section: Introductionmentioning

confidence: 99%

“…The hydroformylation of olefins [1,2] is one of the most widely used homogeneous catalysed reactions with >10 million metric tonnes of aldehydes produced in 2008 [3–12] . Several transition metals such as Ir, Rh, Co, Ru, Fe and Pd have been used to catalyse this reaction, but only Co and Rh are used on an industrial scale due to their high activity and selectivity [3,8,13,14] .…”

Section: Introductionmentioning

confidence: 99%

Understanding Rh‐catalysed Hydroformylation with Phosphite Ligands through Catalyst Speciation Analysis by Operando FlowNMR Spectroscopy

et al. 2023

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Phosphites are industrially important ligands for the Rhcatalysed hydroformylation of olefins because they produce more active catalysts than phosphines, which is mainly due to their strong π-acceptor properties facilitating CO dissociation from the metal centre. Herein, the effect of three prominent phosphite ligands (triphenylphosphite, Alkanox and BiPhePhos) on catalyst speciation during turnover is investigated using multi-nuclear operando FlowNMR spectroscopy. The quantita-tive catalyst distribution maps derived explain activity trends across a range of catalytic reaction conditions that show how phosphites produce more active catalysts, including reduced formation of inactive Rh 0 dimers in the absence of substrate during pre-activation and at the end of the reaction. Additionally, [(alkanox)Rh(acac)] complexes have been found to be of high stability which can be exploited for post-catalytic Rh recovery by simple addition of 2,4-pentanediones.

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“…In particular, rhodium(I) complexes modified with bulky aryl monophosphite ligands were found to lead to highly active, chemo- and regioselective catalysts in the hydroformylation of disubstituted and internal double bounds, under relatively mild conditions [ 14 , 15 , 16 ]. This exceptional activity results from both electronic and stereo effects: on one hand, the π-acidic character of the phosphite weakens the metal-CO bond, thereby allowing a faster CO dissociation; on the other hand, the ligand’s large cone angle allows the coordination of only one phosphite to the metal centre, even when used in large excess, which results in a low global steric hindrance around the metal centre [ 17 , 18 ]. Moreover, the design and synthesis of chiral phosphite ligands also play a key role in the development of asymmetric catalysis [ 19 , 20 , 21 , 22 ].…”

Section: Introductionmentioning

confidence: 99%

Stereoisomeric Tris-BINOL-Menthol Bulky Monophosphites: Synthesis, Characterisation and Application in Rhodium-Catalysed Hydroformylation

et al. 2022

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Four stereoisomeric monoether derivatives, based on axially chiral (R)- or (S)-BINOL bearing a chiral (+)- or (−)-neomenthyloxy group were synthesised and fully characterised by NMR spectroscopy and X-ray crystallography. The respective tris-monophosphites were thereof prepared and fully characterised. The coordination ability of the new bulky phosphites with Rh(CO)2(acac), was attested by 31P NMR, which presented a doublet in the range of δ = 120 ppm, with a 1J(103Rh-31P) coupling constant of 290 Hz. The new tris-binaphthyl phosphite ligands were further characterised by DFT computational methods, which allowed us to calculate an electronic (CEP) parameter of 2083.2 cm−1 and an extremely large cone angle of 345°, decreasing to 265° upon coordination with a metal atom. Furthermore, the monophosphites were applied as ligands in rhodium-catalysed hydroformylation of styrene, leading to complete conversions in 4 h, 100% chemoselectivity for aldehydes and up to 98% iso-regioselectivity. The Rh(I)/phosphite catalytic system was also highly active and selective in the hydroformylation of disubstituted olefins, including (E)-prop-1-en-1-ylbenzene and prop-1-en-2-ylbenzene.

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Hydroformylation

Cited by 28 publications

References 83 publications

Chitosan‐Silica as a Cheap Carrier and Green Soft Ligand for Improved Ru‐catalyzed Hydroformylation

Chitosan‐Silica as a Cheap Carrier and Green Soft Ligand for Improved Ru‐catalyzed Hydroformylation

Understanding Rh‐catalysed Hydroformylation with Phosphite Ligands through Catalyst Speciation Analysis by Operando FlowNMR Spectroscopy

Stereoisomeric Tris-BINOL-Menthol Bulky Monophosphites: Synthesis, Characterisation and Application in Rhodium-Catalysed Hydroformylation

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