Is the Electrophilicity of the Metal Nitrene the Sole Predictor of Metal-Mediated Nitrene Transfer to Olefins? Secondary Contributing Factors as Revealed by a Library of High-Spin Co(II) Reagents

Kalra, A. J.; Bagchi, Vivek; Paraskevopoulou, Patrina; Das, Purak; Lin, Ai Jeng; Sanakis, Yiannis; Raptopoulos, Grigorios; Mohapatra, Sudip; Choudhury, Amitava; Sun, Zhicheng; Cundari, Thomas R.; Stavropoulos, Pericles

doi:10.1021/acs.organomet.1c00267

Cited by 10 publications

(7 citation statements)

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“…The attendant π–π interactions between MeCN and the arene rings may enable observable coordination at ambient temperatures, as related tris-amidylamine cobaltates bearing alkyl substituents have been reported to retain four-coordinate geometries in acetonitrile solution . Examples of trigonal monopyramidal cobalt(II) complexes that do coordinate acetonitrile include those bearing weaker trans donors , and cationic complexes, both of which can be reasoned to exhibit enhanced Lewis acidity. Note that variable-temperature UV–visible spectroscopy measurements for acetonitrile solutions of [NiL OMe ] – show changes potentially indicative of solvent coordination at lower temperatures (Figure S20), whereas ambient-temperature and low-temperature spectra of [ NiL OCH2O ] – in acetonitrile are essentially unchanged (Figure S21), again suggesting that only the nonmacrocyclized ligand permits acetonitrile coordination.…”

Section: Resultsmentioning

confidence: 99%

Coordinatively Unsaturated Metallates of Cobalt(II), Nickel(II), and Zinc(II) Guarded by a Rigid and Narrow Void

et al. 2023

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Both natural enzymatic systems and synthetic porous material catalysts utilize well-defined and uniform channels to dictate reaction selectivities on the basis of size or shape. Mimicry of this design element in homogeneous systems is generally difficult owing to the flexibility inherent in most small molecular species. Herein, we report the synthesis of a tripodal ligand scaffold that orients a narrow and rigid cavity atop accessible metal coordination space. The permanent void is formed through a macrocyclization reaction whereby the 3,5-dihydroxyphenyl arms are covalently linked through methylene bridges. Deprotonative metallation leads to anionic and coordinatively unsaturated complexes of divalent cobalt, nickel, and zinc. An analogous series of trigonal monopyramidal complexes bearing a nonmacrocyclized variant of the tripodal ligand are also reported. Physical characterization of the coordination complexes has been carried out using multiple spectroscopic techniques (NMR, EPR, and UV−vis), cyclic voltammetry, and X-ray diffraction. Complexes of the macrocyclized [L OCH2O ] 3− ligand retain a rigid cavity upon metallation, with this cavity guarding the entrance to the open axial coordination site. Through a combination of spectroscopic and computational studies, it is shown that acetonitrile entry into the void is sterically precluded, disrupting anticipated coordination at the intracavity site.

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Section: Resultsmentioning

confidence: 99%

Coordinatively Unsaturated Metallates of Cobalt(II), Nickel(II), and Zinc(II) Guarded by a Rigid and Narrow Void

et al. 2023

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“…After completion of the reaction, the products were isolated by column chromatography (silica gel) and quantified by 1 H NMR (in CDCl 3 or CD 3 CN) versus an internal standard (4′-methoxyacetophenone). All aziridines, ,, any allylic/benzylic amination products ,, and insertion products (Table ) are known compounds. They have been identified with the assistance of 1 H NMR, by comparison with spectroscopic features reported for authentic samples in the literature.…”

Section: Methodsmentioning

confidence: 99%

“…However, by comparison to the tripodal [(TMG 3 trphen)Cu I ] + reagent noted above, all of these M(II) reagents are by far inferior as catalysts in C−H amination reactions and more modestly yielding in C�C aziridination reactions. Incidentally, when the equatorial TMG residues of the [N 3 N] ligand scaffold are replaced by N-amido residues featuring alkyl, aryl, or acyl substituents, the resulting library of anionic tripodal M(II) reagents (M = Mn, Fe, Co) 39,40 is only effective in selective aziridinations of aromatic olefins, presumably due to the diminished electrophilicity of the active metal nitrene moiety.…”

Section: ■ Introductionmentioning

confidence: 99%

“…Incidentally, when the equatorial TMG residues of the [N 3 N] ligand scaffold are replaced by N-amido residues featuring alkyl, aryl, or acyl substituents, the resulting library of anionic tripodal M(II) reagents (M = Mn, Fe, Co) , is only effective in selective aziridinations of aromatic olefins, presumably due to the diminished electrophilicity of the active metal nitrene moiety.…”

Section: Introductionmentioning

confidence: 99%

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A Comparative Study of Cationic Copper(I) Reagents Supported by Bipodal Tetramethylguanidinyl-Containing Ligands as Nitrene-Transfer Catalysts

Sahoo,

Harfmann,

Bhatia

et al. 2024

ACS Omega

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The bipodal compounds [(TMG 2 biphen N-R )Cu I − NCMe](PF 6 ) (R = Me, Ar (4-CF 3 Ph-)) and [(TMG 2 biphen N-Me )-Cu I −I] have been synthesized with ligands that feature a diarylmethyl-and triaryl-amine framework and superbasic tetramethylguanidinyl residues (TMG). The cationic Cu(I) sites mediate catalytic nitrene-transfer reactions between the imidoiodinane PhI = NTs (Ts = tosyl) and a panel of styrenes in MeCN, to afford aziridines, demonstrating comparable reactivity profiles. The copper reagents have been further explored to execute C−H amination reactions with a variety of aliphatic and aromatic hydrocarbons and two distinct nitrene sources PhI = NTs and PhI = NTces (Tces = 2,2,2-trichloroethylsulfamate) in benzene/HFIP (10:2 v/v). Good yields have been obtained for sec-benzylic and tert-C−H bonds of various substrates, especially with the more electron-deficient catalyst [(TMG 2 biphen N−Ar )Cu I −NCMe](PF 6 ). In conjunction with earlier studies, the order of reactivity of these bipodal cationic reagents as a function of the metal employed is established as Cu > Fe > Co ≥ Mn. However, as opposed to the base-metal analogues, the bipodal Cu reagents are less reactive than a similar tripodal Cu catalyst. The observed fluorophilicity of the bipodal Cu compounds may provide a deactivation pathway.

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“…The reactivity of porphyrinoid (porphyrin, corrole, and phthalocyanine), salen, and oxazoline ligands in aziridination has led to a growing interest among the scientific community in developing nitrogen-donor ligand-based aziridination catalysts with varying properties [48]. A significant number of Fe-and Co-based aziridination catalysts have been reported in the last decade, most of which are supported by nitrogen-donor ligands [51][52][53][54][55][56][57][58][59][60][61][62][63][64][65][66]. In recent years, a number of Fe-based aziridination catalysts supported by oxygen-donor [67,68] and carbon-donor [69][70][71][72][73][74][75] ligands have been reported as well.…”

Section: Introductionmentioning

confidence: 99%

Aziridination Reactivity of a Manganese(II) Complex with a Bulky Chelating Bis(Alkoxide) Ligand

et al. 2022

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Treatment of Mn(N(SiMe3)2)2(THF)2 with bulky chelating bis(alkoxide) ligand [1,1′:4′,1′′-terphenyl]-2,2′′-diylbis(diphenylmethanol) (H2[O-terphenyl-O]Ph) formed a seesaw manganese(II) complex Mn[O-terphenyl-O]Ph(THF)2, characterized by structural, spectroscopic, magnetic, and analytical methods. The reactivity of Mn[O-terphenyl-O]Ph(THF)2 with various nitrene precursors was investigated. No reaction was observed between Mn[O-terphenyl-O]Ph(THF)2 and aryl azides. In contrast, the treatment of Mn[O-terphenyl-O]Ph(THF)2 with iminoiodinane PhINTs (Ts = p-toluenesulfonyl) was consistent with the formation of a metal-nitrene complex. In the presence of styrene, the reaction led to the formation of aziridine. Combining varying ratios of styrene and PhINTs in different solvents with 10 mol% of Mn[O-terphenyl-O]Ph(THF)2 at room temperature produced 2-phenylaziridine in up to a 79% yield. Exploration of the reactivity of Mn[O-terphenyl-O]Ph(THF)2 with various olefins revealed (1) moderate aziridination yields for p-substituted styrenes, irrespective of the electronic nature of the substituent; (2) moderate yield for 1,1′-disubstituted α-methylstyrene; (3) no aziridination for aliphatic α-olefins; (4) complex product mixtures for the β-substituted styrenes. DFT calculations suggest that iminoiodinane is oxidatively added upon binding to Mn, and the resulting formal imido intermediate has a high-spin Mn(III) center antiferromagnetically coupled to an imidyl radical. This imidyl radical reacts with styrene to form a sextet intermediate that readily reductively eliminates the formation of a sextet Mn(II) aziridine complex.

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Is the Electrophilicity of the Metal Nitrene the Sole Predictor of Metal-Mediated Nitrene Transfer to Olefins? Secondary Contributing Factors as Revealed by a Library of High-Spin Co(II) Reagents

Cited by 10 publications

References 266 publications

Coordinatively Unsaturated Metallates of Cobalt(II), Nickel(II), and Zinc(II) Guarded by a Rigid and Narrow Void

Coordinatively Unsaturated Metallates of Cobalt(II), Nickel(II), and Zinc(II) Guarded by a Rigid and Narrow Void

A Comparative Study of Cationic Copper(I) Reagents Supported by Bipodal Tetramethylguanidinyl-Containing Ligands as Nitrene-Transfer Catalysts

Aziridination Reactivity of a Manganese(II) Complex with a Bulky Chelating Bis(Alkoxide) Ligand

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