Chromium complexes based on thiophene–imine ligands for ethylene oligomerization

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In this work, a new family of chromium complexes supported by bis(pyrazolyl)thioether/amine ligands containing pendant O‐ and N‐donor groups CrCl3{S‐bis[(3,5‐DMPz)methyl]sulfide} (2a), CrCl3{N‐bis[(3,5‐DMPz)benzylamine]} (2b), CrCl3{N‐bis[(3,5‐DMPz)butylamine]} (2c), [CrCl2{N‐bis[(3,5‐DMPz)methyl][(2‐pyridinyl)methyl]amine}]Cl (2d), [CrCl2{N‐bis[(3,5‐DMPz)methyl][quinoline]amine}]Cl (2e), [CrCl2{N‐bis[3,5‐DMPz‐methyl][EtNMe2]amine}]Cl (2f), CrCl3{N‐bis[(3,5‐DMPz)methyl][2‐methoxyphenyl]amine} (2g), and CrCl3{N‐bis[2‐(3,5‐DMPz)methyl][(2‐pyridyl)ethyl]amine} (2h) were synthetized and characterized by elemental analysis and Fourier transform infrared spectroscopy (FTIR) spectroscopy. Density functional theory (DFT) calculations demonstrated that the pendant group as well as the spacer between the N‐donor group and the central amine nitrogen have strong influence on the coordination motif of the ligand. Thus, 1d–1f act as tetradentate ligands while 1g and 1h preferably coordinated to the chromium metal center in a tridentate [N,N,N] mode fashion. The catalytic performance of 2a–2h is strongly influenced by the nature of the central bridging atom (S, N) as well as the pendant O‐ and N‐donor group. Upon activation with methylaluminoxane (MAO), chromium precatalysts 2a–2c, 2e, and 2f generated active systems producing oligomers ranging from C4 to C12+ with a high selectivity for α‐olefins (>82.4%). On the other hand, precatalysts bearing pyridine (2d and 2h) and methoxy (2g) functionalized amine bis (pyrazolyl) ligands exclusively produce polyethylene (PE) with activities in the range of 107.2–372.0 kg of PE·mol[Cr]−1 h−1.

Section: Introductionmentioning

confidence: 99%

Bis(pyrazolyl)thioether/amine‐chromium(III) catalysts bearing pendantO‐ andN‐donor group for oligomerization and polymerization of ethylene

Oliveria

Oliboni

Stieler

et al. 2022

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“…In the paper described herein, we aimed to design and prepare new diamine-diphenolate ligands, to be considered salan derivative ligands, typically ligands that contain same substituents on the phenolate arms and different linkage between nitrogen atoms and study the structure and catalytic properties of their resulting titanium catalysts (see Scheme 1), in the higher olefins up to 1-decene oligomerization. [20][21][22][23] Our goals were gaining more insight into the activity of salan catalysts with changing ligand structure and possibly synthesizing complexes which will be capable to produce controllable molecular weight 1-decene based oligomers. [24] 2…”

Section: Introductionmentioning

confidence: 99%

1‐Decene oligomerization by new complexes bearing diamine‐diphenolates ligands: Effect of ligand structure

Hanifpour

Bahri‐Laleh

Nekoomanesh‐Haghighi

et al. 2021

A series of new titanium (IV) complexes bearing tetradentate diamine‐diphenolates, homologous to [ONNO] salan type ligands: [Ti{2,2′‐(OC6H2–4,6‐tBu2)2NHC3H6NH}(Cl)2] (Cat1), [Ti{2,2′‐(OC6H2–4,6‐tBu2)2NHC4H8NH}(Cl)2] (Cat2), and [Ti{2,2′‐(OC6H2–4,6‐tBu2)2NHC6H4NH}(Cl)2] (Cat3) were synthesized and fully characterized by elemental analysis and NMR spectroscopy. All three synthesized catalysts, after activation with ([Ph3C][B(C6F5)4]) as a cocatalyst, exhibited high activities in 1‐decene oligomerization experiments. Gel permeation chromatography (GPC) analysis showed that molecular weight of the obtained oligomers had a close relationship with employed ligand structures, so that by increasing length of the aliphatic linkage between nitrogen donor atoms, PDI (Mw/Mn) shifted to the higher values. 1‐decene oligomers obtained by the Cat3 exhibited highest isotactic value (92% tacticity). Kinetic calculations allowed us to formulate the elementary reaction steps in oligomerization process of the 1‐decene. At the viscosity characterization, KV100 amounts of 2.9, 3.9, and 4.1 cSt were determined for synthesized oligomers with Cat1, Cat2, and Cat3, respectively. High catalyst activity, capability of producing PAOs with KV100 < 6, less toxicity and corrosiveness of the catalytic system (compared to commercialized process based on the hazardous BF3 catalyst), and simplicity of the preparation procedure are the merits of the new reported catalysts.

“…[ 13–16 ] In this way, significant efforts have been dedicated to the synthesis of new families of ligands based on a wide variety of donor‐group combinations aiming to generate more efficient chromium catalyst systems that are capable of selectively forming α‐olefins with high productivities. [ 17–81 ] In particular, chromium catalysts stabilized by pyrazolyl‐based tridentate ligands have been successfully synthetized and their catalytic application in ethylene oligomerization explored in details. [ 51,81–91 ] Selected examples are presented in Chart 1.…”

Section: Introductionmentioning

confidence: 99%

Chromium Complexes Supported by Phenyl Ether‐Pyrazolyl [N,O] Ligands as Catalysts for the Oligo‐ and Polymerization of Ethylene

Milani

Casagrande

2020

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A new series of Cr (III) complexes [Cr{1‐(3‐phenoxypropyl)‐1H‐pyrazole}Cl3]2 (Cr1), [Cr{1‐(3‐phenoxypropyl)‐3,5‐dimethyl‐1H‐pyrazole}Cl3]2 (Cr2), and [Cr{1‐(3‐phenoxypropyl)‐3‐phenyl‐1H‐pyrazole}Cl3]2 (Cr3) have been synthesized and characterized by elemental analysis, high‐resolution mass spectrometry (HRMS) and IR spectroscopy. Upon activation with methylaluminoxane (MAO), chromium precatalysts Cr2 and Cr3 showed moderate activity in ethylene oligomerization [TOF = 17,900–29,200 mol (ethylene)·mol (Cr)−1·h−1 at 80 °C] with Schultz‐Flory distribution of oligomers (K = 0.54–0.66) and production of polymer varying from 2.8 to 6.7 wt.%. On the other hand, under identical oligomerization conditions, Cr1/MAO behaved as a polymerization catalyst generating predominantly polyethylene (63.7 wt%). The amount of 1‐butene is the largest component in the liquid fraction suggesting that these precatalysts operate via a Cossee‐Arlman mechanism. The catalytic activities, selectivity and product distribution are quite sensitive to the R‐group at the 3‐ and 5‐position of the pyrazolyl ring. Based on the electronic and steric effects of R‐ substituents, it is possible to stablish a trend of activity: Cr2(PzMe2) > Cr3(PzPh) > Cr1(Pz). Moreover, the effect of oligomerization parameters (cocatalyst, temperature, [Al]/[Cr] molar ratio, time) on the activity and on the product distribution were examined.