Insertion of Terminal and Internal Acetylenes into the Zr−μ-Methylene Bond of the Dinuclear Cationic Zirconium Complex [{Zr(η5-C5H5)}2(μ-CH2)(μ-Cl)(μ-η5-C5H4-η5-C5H4)][BMe(C6F5)3]. Synthetic Aspects, NMR Spectroscopic Study, and Dynamic Behavior in Solution

Royo, Eva Sáenz; Royo, and Pascual; Cuenca, Tomás; Galakhov, Mikhail

doi:10.1021/om000664h

Cited by 19 publications

(8 citation statements)

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“…The behavior described here for compound 1c parallels that observed for the related dinuclear titanium compound [(TiBz 2 ) 2 (μ-{η 5 -C 5 H 4 SiMe 2 O} 2 )], for which the benzyl-bridged intermediate was unstable in aromatic solvents, decomposing to give unidentified paramagnetic species . The substitution of the benzyl by a halide bridge occurring in halogenated solvents is clearly favored by the π-donating ability of this substituent, which increases the electron density, reducing their positive charge. − Cationic dinuclear group 4 complexes with halide bridges have also been formed by rearrangement of mononuclear cationic derivatives in halogenated solvents. ,, …”

Section: Resultssupporting

confidence: 71%

Mono- and Dinuclear Cyclopentadienylsiloxo Titanium Complexes: Synthesis, Reactivity, and Catalytic Polymerization Applications

et al. 2008

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Hydrolysis of the (dichloromethylsilyl)cyclopentadienyl titanium compound [Ti(η5-C5Me4SiMeCl2)Cl3] gave the metallasiloxane dinuclear complex [(TiCl2)2(μ-{(η5-C5Me4SiMeO)2(μ-O)})] (1a). Addition of 4 equiv of RMgCl (R = Me, Bz) to 1a afforded the corresponding tetraalkyl dititanium derivatives [(TiR2)2(μ-{(η5-C5Me4SiMeO)2(μ-O)})] (R = Me 1b, Bz 1c). The benzyl compound 1c reacted with E(C6F5)3 (E = B, Al) and [Ph3C][B(C6F5)4] to give the bridged dititanium compounds [(TiBz)2(μ-{(η5-C5Me4SiMeO)2(μ-O)})(μ-X)][Q] (Q = BzB(C6F5)3; X = Br, 2Br; Cl, 2Cl; F, 2F; Q = BzAl(C6F5)3; X = Cl, 3Cl; Q = B(C6F5)4; X = Bz, 4Bz; Cl, 4Cl) by benzyl abstraction and further reaction with the corresponding halogenated solvents. The addition of excess B(C6F5)3 to 1c gave the bis(zwitterionic) benzyl intermediate [(TiBz{η6-PhCH2B(C6F5)3})2(μ-{(η5-C5Me4SiMeO)2(μ-O)})] (6), which evolved into the bis(zwitterionic) fulvene derivative [(Ti{η6-PhCH2B(C6F5)3})2(μ-{(η5-C5Me3(η1-CH2)SiMeO)2(μ-O)})] (5). Related mononuclear siloxo compounds [TiCp*R2(OSiiPr3)] (Cp* = η5-C5Me5; R = Cl, 7a; Me, 7b) were obtained from the reaction of [TiCp*R3] (R = Cl, Me) with HOSiiPr3. Compound 7b reacted with E(C6F5)3 (E = B, Al) in C6D6, affording the thermally stable ion-paired derivatives [TiCp*Me(OSiiPr3){MeE(C6F5)3}] (E = B, 8B; Al, 8Al). The chloro dinuclear 1a and mononuclear 7a complexes were tested as ethylene polymerization catalysts and the alkyl complexes 1b, 1c, and 7b as methylmethacrylate polymerization catalysts.

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Section: Resultssupporting

confidence: 71%

Mono- and Dinuclear Cyclopentadienylsiloxo Titanium Complexes: Synthesis, Reactivity, and Catalytic Polymerization Applications

et al. 2008

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“…Intermediate A evolves via β-H elimination from the 1,3-μ 2 -propylene group to the more stable structure B ( rac isomer, Δ E = −16.1 kcal/mol) with a μ 2 -H bridge, methyl displacement toward to the Ti2 center, and a new allylic fragment at Ti1 . A similar Ti 2 complex, reminiscent of intermediate B , was observed experimentally by Cuenca et al . DFT yields similar results for meso- 5 ; however, intermediates A and B are far less stable than rac- 5 (Δ E = −1.7 kcal/mol and −2.5 kcal/mol for A and B , respectively).…”

Section: Discussionmentioning

confidence: 99%

Distinctive Stereochemically Linked Cooperative Effects in Bimetallic Titanium Olefin Polymerization Catalysts

et al. 2017

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The complex (μ-Me 2 C-3,3′){(η 5 -cyclopentadienyl)[1-Me 2 Si-( t BuN)](TiMe 2 )} 2 (3) was prepared as a new binuclear catalyst motif for homogeneous olefin polymerization. Complex 3 exists as rac-3 and meso-3 diastereomers, which can be separated and characterized by solution NMR spectroscopy and single-crystal X-ray diffraction. While meso-3 has high thermal stability, rac-3 undergoes thermolysis in solution to quantitatively form the dimeric methylidene complex (μ-Me 2 C-3,3′){(η 5 -cyclopentadienyl)[1-Me 2 Si( t BuN)][(μ-CH 2 )Ti]} 2 (rac-4). Activation of rac-3 and meso-3 with 1 equiv of Ph(5; rac-5 and meso-5, respectively). Interestingly, meso-5 is stable in the presence of an additional 1 equiv of Ph] 2 (rac-6) as indicated by multinuclear NMR spectroscopy and DFT computation. meso-3 reacts with 2 equiv of B(C 6 F 5 ) 3 to yield meso-[(μ-CMe 2 -3,3′){(η 5 -cyclopentadienyl)[1-Me 2 Si( t BuN)]} 2 (μ-CH 2 )(μ-CH 3 )Ti 2 ] + MeB(C 6 F 5 ) 3 − (meso-7) containing the same meso-5 cation but with a MeB(C 6 F 5 ) 3 − counteranion. These findings, along with catalytic results, indicate that rac-3 and meso-3 remain structurally intact during polymerization, consistent with the observed diastereoselectivity effects. Under identical ethylene/1octene copolymerization conditions, only activated bimetallic rac-3 produces appreciable polymer, with meso-3 exhibiting low activity, but both yield polymer with a branch density >2× that of the monometallic control [(3-t Bu-C 5 H 3 )SiMe 2 N t Bu]TiMe 2 (Ti 1 ). In ethylene/styrene copolymerizations, rac-3 produces polymers with 3.1× higher M n and 2.1× greater styrene incorporation versus Ti 1 , while meso-3 catalyzes only ethylene-free styrene homopolymerization. In 1-octene homopolymerizations, meso-3 + B(C 6 F 5 ) 3 (i.e., meso-7) produces highly isotactic poly-1-octene (mmmm 91.7%), while rac-3 + Ph 3 C + B(C 6 F 5 ) 4 − (i.e., rac-5), rac-3 + B(C 6 F 5 ) 3 (i.e., rac-7), and meso-3 + Ph 3 C + B(C 6 F 5 ) 4 − (i.e., meso-5) produce only atactic poly-1-octene. These bimetallic polymerization catalysts exhibit distinctive cooperative effects influencing product M n , tacticity, and comonomer selection, demonstrating that binuclear catalyst stereochemical factors are significant.

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“…[25] It should be noted that the 1 H NMR spectrum of 1 displays two singlets for the Cp ligands and eight well-resolved multiplets (see the Experimental Section) for the fulvalene ligand (resulting in two ABCD spin systems). [19,26] We did not observe a Ga À H IR stretch in the expected region (1800-2100 cm À ). [27][28][29][30] In an effort to better elucidate the nature of the hydride, we performed density functional theory (DFT) computations on 1 a, in which the meta terphenyl ligand of 1 has been replaced with a 2,6-dimethylphenyl ligand.…”

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confidence: 48%

“…[11] The Ga ( . [19] Other 1 H NMR signals for bridging zirconium hydrides range from d = À5.32 to 0.95 ppm, [20][21][22][23] whereas terminal zirconium hydride 1 H NMR signals may range from d = 3.03 to 7.25 ppm. [20][21][22][23][24] The computed 1 H NMR spectrum of a model of 1, [(C 10 H 8 )(CpZr) 2 (m-H)(m-Cl)(mGaR)] (1 a; R = 2,6-Me 2 C 6 H 3 ), at the GIAO-PW91PW91/ LANL2DZ/-/PW91/LANL2DZ level showed that the computed hydride d value of À5.00 ppm is comparable to the experimental value observed for 1.…”

mentioning

confidence: 99%

A Trimetallic Fulvalene‐Bridged Dizirconocene–Gallium Complex

Quillian¹,

Wang²,

Wannere³

et al. 2007

Angew Chem Int Ed

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Insertion of Terminal and Internal Acetylenes into the Zr−μ-Methylene Bond of the Dinuclear Cationic Zirconium Complex [{Zr(η⁵-C₅H₅)}₂(μ-CH₂)(μ-Cl)(μ-η⁵-C₅H₄-η⁵-C₅H₄)][BMe(C₆F₅)₃]. Synthetic Aspects, NMR Spectroscopic Study, and Dynamic Behavior in Solution

Cited by 19 publications

References 71 publications

Mono- and Dinuclear Cyclopentadienylsiloxo Titanium Complexes: Synthesis, Reactivity, and Catalytic Polymerization Applications

Mono- and Dinuclear Cyclopentadienylsiloxo Titanium Complexes: Synthesis, Reactivity, and Catalytic Polymerization Applications

Distinctive Stereochemically Linked Cooperative Effects in Bimetallic Titanium Olefin Polymerization Catalysts

A Trimetallic Fulvalene‐Bridged Dizirconocene–Gallium Complex

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