Azavinylidene Complexes from Coupling Reactions of Organonitriles with Phosphines

Lee, Kui Fun; Yang, Tilong; Tsang, Long Yiu; Sung, Ho Yung; Williams, Ian D.; Lin, Zhenyang; Jia, Guocheng

doi:10.1021/acs.organomet.0c00704

Cited by 7 publications

(13 citation statements)

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“…Phosphonium-substituted rhenium azavinylidene complexes can be directly produced from the coupling reactions of nitriles with phosphines. 7 DFT studies on aromaticity Density functional theory (DFT) studies 8 were performed on the model complex M-N (Table 1) to examine the aromaticity of complex 2, in which PMePh 2 was replaced by PH 3 to reduce the calculation cost. Nucleus-independent chemical shift (NICS) 9 calculations were carried out.…”

Section: Synthesis and Structural Characterizationmentioning

confidence: 99%

“…Hydrogen atoms on the phenyl and methyl groups were omitted for clarity. Selected bond lengths [Å] and angles [°]: Re1-C4 1.9013(18), Re1-C5 2.1975(18), Re1-N1 2.0525(17), C1-N1 1.295(3), C1-C2 1.434(3), C2-C3 1.418(3), C3-C4 1.423(3), C4-C5 1.425(3), Re1-Cl1 2.4733(5), Re1-Cl2 2.4311(5), Re1-Cl3 2.4570(5), Re1-P2 2.4053(5), C5-P1 1.7874(18), C1-Cl4 1.7342(19), C4-Re1-C5 39.87(7), Re1-C4-C5 81.33(11), Re1-C4-C3 140.88(14), C2-C3-C4 119.94(17), C1-C2-C3 117.72(17), N1-C1-C2 124.13(18), Re1-N1-C1 137.27(14), and C4-Re1-N1 78.12(7).…”

mentioning

confidence: 99%

“…Hydrogen atoms on the phenyl and methyl groups were omitted for clarity. Selected bond lengths [Å] and angles [°]: Re1-C1 2.190(5), Re1-C2 1.876(5), Re1-N1 1.996(4), N1-C5 1.331(6), C4-C5 1.439(6), C3-C4 1.414(7), C2-C3 1.441(6), C1-C2 1.424(6), Re1-Cl1 2.4873(13), Re1-Cl2 2.4553(12), Re1-Cl3 2.4010(13), Re1-P2 2.4222(14), C5-P1 1.819(5), C1-P3 1.783(5), C1-Re1-C2 40.06(18), Re1-C2-C1 81.9(3), Re1-C2-C3 141.6(4), C2-C3-C4 118.4(4), C3-C4-C5 118.7(4), N1-C5-C4 122.6(5), Re1-N1-C5 138.3(4), C2-Re1-N1 78.84(19), and N1-C5-P1 116.8(4).…”

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Synthesis, structure and aromaticity of metallapyridinium complexes

et al. 2022

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Synthesis, structure and aromaticity of metallapyridinium complexes

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“…The cations are based on a diiron core comprising the Cp ligands in cis position, bridging aminocarbyne and CO ligands, and terminal CO and nitrile ligands. The C(3)–N(1) interaction [1.288(7)–1.297(4) Å] displays some double-bond character, as typically found in analogous complexes [ 19 , 20 , 21 , 26 , 27 , 57 , 58 ], highlighting the hybrid aminocarbyne/iminium nature of the {µ-CN(Me)(Y)} ligand ( Scheme 4 ). In all structures, the nitrile ligand is on the same side with respect to the bulkier aminocarbyne substituent Y (Z isomer).…”

Section: Resultsmentioning

confidence: 93%

“…They most commonly behave as monodentate ( end-on ) ligands, and have been widely employed as weakly coordinating agents in complexes of low- to middle-valent transition metals, since their substitution by more strongly coordinating ligands is a convenient strategy to access a multitude of derivatives, catalysts and materials [ 4 , 5 , 6 , 7 , 8 , 9 , 10 , 11 ]. Furthermore, nitrile ligands are usually susceptible to nucleophilic attack [ 12 , 13 , 14 ] and may be engaged in a great variety of chemical transformations mediated by the adjacent metal centre, either catalytic [ 15 , 16 , 17 , 18 ] or stoichiometric [ 12 , 19 , 20 , 21 , 22 , 23 ].…”

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confidence: 99%

A Comprehensive Analysis of the Metal–Nitrile Bonding in an Organo-Diiron System

et al. 2021

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Nitriles (N≡CR) are ubiquitous in coordination chemistry, yet literature studies on metal–nitrile bonding based on a multi-technique approach are rare. We selected an easily-available di-organoiron framework, containing both π-acceptor (CO, aminocarbyne) and donor (Cp = η5−C5H5) ligands, as a suitable system to provide a comprehensive description of the iron–nitrile bond. Thus, the new nitrile (2–12)CF3SO3 and the related imine/amine complexes (8–9)CF3SO3 were synthesized in 58–83% yields from the respective tris-carbonyl precursors (1a–d)CF3SO3, using the TMNO strategy (TMNO = trimethylamine-N-oxide). The products were fully characterized by elemental analysis, IR (solution and solid state) and multinuclear NMR spectroscopy. In addition, the structures of (2)CF3SO3, (3)CF3SO3, (5)CF3SO3 and (11)CF3SO3 were ascertained by single crystal X-ray diffraction. Salient spectroscopic data of the nitrile complexes are coherent with the scale of electron-donor power of the R substituents; otherwise, this scale does not match the degree of Fe → N π-back-donation and the Fe–N bond energies, which were elucidated in (2–7)CF3SO3 by DFT calculations.

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[ReH₃(PPh₃)₄] – A Key Compound in the Rhenium Hydride Chemistry

Jungfer

Abram

2023

Chemistry A European J

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The chemistry of the rhenium trihydrido complex [ReH3(PPh3)4] (1) has been reinvestigated. An improved synthesis and the solid‐state structure of the compound as well as several reactions are reported. The solid‐state structure of 1 is similar to that of [TcH3(PPh3)4] having a capped‐octahedral coordination sphere. The PPh3 ligands surround the Re atom in a trigonal‐pyramidal mode with a short apical Re−P bond (2.300(2) Å) and three longer basal bonds (2.429(2)–2.449(2) Å). Reactions of 1 with monodentate phosphines such as PMe3 or PBu3 give the mono‐substituted complexes [ReH3(PPh3)3(PMe3)] (2) and [ReH3(PPh3)3(PBu3)] (3) under retention of the apical PPh3 ligand and substitution of one of the basal PPh3 ligands. The stability of the phosphine trihydride complexes decreases in the order PPh3>PMe3>PBu3. Treatment of [ReH3(PPh3)4] with trityl hexafluorophosphate in CH3CN does not result in a hydride abstraction, but gives the tetrahydrido cation [ReH4(NCCH3)(PPh3)3]+ (4), while reactions with nitriles give unstable azavinylidene complexes of the composition [ReH2(PPh3)3(NC(H)R)] (5). They are formed by an insertion of the nitrile into a Re−H bond. The solid‐state structure of the methyl derivative [ReH2(PPh3)3(NC(H)CH3)] (5 a) was determined showing a linear Re−N−C unit with rhenium−nitrogen and nitrogen−carbon double bonds, while the N=CH−C bond is clearly bent with an angle of 124°. Two previously unknown polymorphs of [ReH5(PPh3)3] were isolated from reactions of 1 with HOC6H3(CH3)2 and thiourea after prolonged heating in toluene and characterized by IR spectroscopy and X‐ray diffraction.

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Azavinylidene Complexes from Coupling Reactions of Organonitriles with Phosphines

Cited by 7 publications

References 95 publications

Synthesis, structure and aromaticity of metallapyridinium complexes

Synthesis, structure and aromaticity of metallapyridinium complexes

A Comprehensive Analysis of the Metal–Nitrile Bonding in an Organo-Diiron System

[ReH₃(PPh₃)₄] – A Key Compound in the Rhenium Hydride Chemistry

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Azavinylidene Complexes from Coupling Reactions of Organonitriles with Phosphines

Cited by 7 publications

References 95 publications

Synthesis, structure and aromaticity of metallapyridinium complexes

Synthesis, structure and aromaticity of metallapyridinium complexes

A Comprehensive Analysis of the Metal–Nitrile Bonding in an Organo-Diiron System

[ReH3(PPh3)4] – A Key Compound in the Rhenium Hydride Chemistry

Contact Info

Product

Resources

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[ReH₃(PPh₃)₄] – A Key Compound in the Rhenium Hydride Chemistry