Ureate Titanium Catalysts for Hydroaminoalkylation: Using Ligand Design to Increase Reactivity and Utility

Manßen, Manfred; Deng, Danfeng; Zheng, Cameron H. M.; DiPucchio, Rebecca C.; Chen, Dafa; Schafer, Laurel L.

doi:10.1021/acscatal.1c00014

Cited by 18 publications

(29 citation statements)

References 77 publications

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“…While there are a few examples of late-transition-metal complexes with the aziridine binding motif, − the vast majority of isolated examples contain hard Lewis acidic early transition metals with bonding motifs most consistent with the metallaaziridine formulation . The latter variant is particularly interesting because these complexes can be used as α-amino carbanion equivalents, as opposed to π-bound electrophiles, to access a variety of α-substituted nitrogen-containing molecules in stoichiometric or catalytic transformations involving unsaturated molecules. − For example, metallaaziridine species are key intermediates in early-transition-metal-catalyzed hydroaminoalkylation reactions, where the α-C–H bond of an amine is added across an unsaturated C–C bond of an alkene − or an alkyne , in a 100% atom-economical fashion (see Scheme b).…”

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confidence: 99%

Reversible C–H Activation in Zirconaaziridine Species: Characterization and Bonding of a Bridging (Amino)alkylidene Complex Active in Alkyne Hydroaminoalkylation

2022

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Efforts to synthesize a low-coordinate zirconaaziridine complex supported by a bis(ureate) ligand resulted in the formation of bridging aminoalkylidene 2. Complex 2 is a rare example of an aminoalkylidene complex featuring a μ(η2:η2)-N,C binding mode. This complex was fully characterized by single-crystal X-ray diffraction, NMR spectroscopy, and LIFDI-MS. Analysis of the natural localized molecular orbitals (NLMOs) showed a σ-bonding interaction between the alkylidene carbon and each zirconium center with significant delocalization of the Zr1–C1 σ bond into Zr2, thereby explaining the significant differences in the Zr–C bond lengths observed in the solid state. A solution-phase equilibrium between complex 2 and the putative zirconaaziridine species was supported by evaluating the reactivity of 2 in alkyne hydroaminoalkylation. The reaction of diphenylacetylene with complex 2 produced a five-membered metallacycle product, a key intermediate in alkyne hydroaminoalkylation. This reaction was greatly accelerated in the presence of pyridine, suggesting that the presence of neutral donors is essential to favor the formation of reactive zirconaaziridine complexes. In addition, the catalytic activity of complex 2 in the benchmark hydroaminoalkylation reaction of diphenylacetylene with N-benzylaniline was established.

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Reversible C–H Activation in Zirconaaziridine Species: Characterization and Bonding of a Bridging (Amino)alkylidene Complex Active in Alkyne Hydroaminoalkylation

2022

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“…Also, less toxic and less expensive early-transition metals (ETM) from groups 3, 4 and 5, including earth abundant metals like titanium can be used as catalysts. [22][23][24][25][26] In recent years this strategy has proven to be an efficient, thermally promoted reaction. However, like many other C-H functionalization reactions, this transformation often requires very high reaction temperatures of up to 180 °C.…”

Section: Introductionmentioning

confidence: 99%

Tantalum Ureate Complexes for Photocatalytic Hydroaminoalkylation

Hao,

Manßen,

Schafer

2022

Preprint

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Using a tantulum ureate pre-catalyst, photocatalytic hydroaminoalkylation of unactivated alkene with unprotected amine at room temperature is demonstrated. The conbination of Ta(CH2SiMe3)3Cl2 and ureate ligand with saturated cyclic backbone resulted in unique reactivity. The substrate scope of Ta photocatalytic hydroaminoalkylation (β-alkylation of amine) was evaluated. Preliminary investigation on reaction mechanism suggests both similarities and differences with Ta catalyzed hydroaminoalkyaltion under thermo conditions

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“…Our group recently showed that highly active tantalum and titanium ureate hydroaminoalkylation catalysts can be prepared in situ for the efficient alkylation of both aryl and alkyl N -methylated secondary amines. − Although reactivity with N -heterocycles was not achieved, this earlier work showcased the tunable nature of ureate ligand salts to improve catalytic activity and enhance substrate scope. Here, we report a tantalum ureate catalyst for the rapid α-C–H alkylation of saturated N -heterocycles with activated and unactivated alkene coupling partners (Figure c).…”

Section: Introductionmentioning

confidence: 99%

Direct, Catalytic α-Alkylation of N-Heterocycles by Hydroaminoalkylation: Substrate Effects for Regiodivergent Product Formation

et al. 2021

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Saturated N-heterocycles are prevalent in pharmaceutical and agrochemical industries, yet remain challenging to catalytically alkylate. Most strategies for C–H activation of these challenging substrates use protected amines or high loadings of precious metal catalysts. We report an early transition-metal system for the broad, robust, and direct alkylation of unprotected amine heterocycles with simple alkenes. Short reaction times are achieved using an in situ generated tantalum catalyst that avoids the use of bases, excess substrate, or additives. In most cases, this catalyst system is selective for the branched reaction product, including examples of products that are generated with excellent diastereoselectivity. Alkene electronic properties can be exploited for substrate-modified regioselectivity to access the alternative linear amine alkylation product with a group 5 catalyst. This method allows for the facile isolation of unprotected N-heterocyclic products, as useful substrates for further reactivity.

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Ureate Titanium Catalysts for Hydroaminoalkylation: Using Ligand Design to Increase Reactivity and Utility

Cited by 18 publications

References 77 publications

Reversible C–H Activation in Zirconaaziridine Species: Characterization and Bonding of a Bridging (Amino)alkylidene Complex Active in Alkyne Hydroaminoalkylation

Reversible C–H Activation in Zirconaaziridine Species: Characterization and Bonding of a Bridging (Amino)alkylidene Complex Active in Alkyne Hydroaminoalkylation

Tantalum Ureate Complexes for Photocatalytic Hydroaminoalkylation

Direct, Catalytic α-Alkylation of N-Heterocycles by Hydroaminoalkylation: Substrate Effects for Regiodivergent Product Formation

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