Asymmetric NH Insertion Reaction Cooperatively Catalyzed by Rhodium and Chiral Spiro Phosphoric Acids

Xu, Bin; Zhu, Shou‐Fei; Xie, Xiulan; Shen, Jun-Jie; Zhou, Qi‐Lin

doi:10.1002/anie.201105485

Cited by 301 publications

(116 citation statements)

References 49 publications

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“…The reaction depicted in Scheme 2 is selected as our subject. 5 In light of our calculations, the formation of the ammonium ylides (B and C) is disfavored and the [1,2]-proton shift for both species suffers from the inaccessible overall barrier to give the N−H insertion product at room temperature. On the other hand, the formation of the enamine intermediate is more favorable kinetically as well as thermodynamically.…”

Section: Introductionmentioning

confidence: 82%

Mechanistic Insight into Asymmetric N–H Insertion Cooperatively Catalyzed by a Dirhodium Compound and a Spiro Chiral Phosphoric Acid

Wang¹,

Song²,

Guo³

et al. 2014

Organometallics

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The insertion of a carbenoid into an N−H bond of an amine cooperatively catalyzed by a dirhodium catalyst and a spiro chiral phosphoric acid has been investigated in detail using density functional theory methods. Calculations indicate that the reaction begins with the nucleophilic amine attacking at the carbenoid, forming a metal-associated ammonium ylide first followed by a rapid proton transfer to afford a metal-associated enamine intermediate. Subsequently, the enamine intermediate dissociates from the metal and yield a more stable sevenmembered-ring conformation via an intramolecular hydrogen-bond exchange. Formation of the enamine intermediate requires an overall barrier of 5.7 kcal/mol and is exergonic by 5.1 kcal/mol. Calculations demonstrated that, although the conversion of the achiral enamine into the N−H insertion product can be facilitated efficiently by the dirhodium catalyst through a two-step process, it can be compressed to a large extent. This is due to the more competitive decomposition of the diazoacetate catalyzed by the dirhodium catalyst, which can give a carbenoid for the next catalytic cycle. Meanwhile, formation of the carbenoid is considerably exergonic, which can promote the direct [1,3]-proton shift of enamine. However, in the presence of the spiro chiral phosphoric acid, the asymmetric proton induction of enamine is greatly favored, requiring an activation free energy of 6.0 kcal/mol to afford the major R product. This agrees well with the experimental observation.

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Section: Introductionmentioning

confidence: 82%

Mechanistic Insight into Asymmetric N–H Insertion Cooperatively Catalyzed by a Dirhodium Compound and a Spiro Chiral Phosphoric Acid

Wang¹,

Song²,

Guo³

et al. 2014

Organometallics

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“…An asymmetric N─H insertion reaction of methyl α-diazo-α-phenylacetate into the N─H bond of tert-butyl carbamate (BocNH 2 ) cooperatively catalyzed by dirhodium(II) carboxylates and chiral spiro phosphoric acids (SPAs) allows to reach high yields and enantioselectivities [9]. An asymmetric N─H insertion reaction of methyl α-diazo-α-phenylacetate into the N─H bond of tert-butyl carbamate (BocNH 2 ) cooperatively catalyzed by dirhodium(II) carboxylates and chiral spiro phosphoric acids (SPAs) allows to reach high yields and enantioselectivities [9].…”

Section: Hydrogen Bonding Cooperation With Coordinationmentioning

confidence: 99%

“…Proposed mechanism of insertion of carbene from methyl α-diazo-α-phenylacetate into BocNH 2 [9]. deprotonate the isocyanoacetate.…”

Section: Scheme 184mentioning

confidence: 99%

Cooperation of Non‐covalent Interactions and Coordination in Catalysis

Maharramov

Mahmudov

Kopylovich

et al. 2016

Non‐covalent Interactions in the Synthesis and Design of New Compounds

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“…Eur.J.2015, 21,10671 -10675 www.chemeurj.org synthetic methodology for natural and unnaturala mino acids. [16] Ap ossible mechanism for the [tBu-PhBidine-Rh(OAc) 2 ]-catalyzed asymmetricM annich reaction is shown in Scheme 3. ESI-MS analysiso nt he mixture of [tBu-PhBidine-Rh(OAc) 2 ]a nd malononitrile gave an ew ion peak at m/z = 1043.3766, corresponding to …”

Section: Scheme2transformation Of Mannich Adductsmentioning

confidence: 99%

Chiral Bis(imidazolidine)‐Derived NCN Pincer Rh Complex for Catalytic Asymmetric Mannich Reaction of Malononitrile with N‐Boc Imines

Arai

Moribatake

Masu

2015

Chemistry A European J

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Chiral bis(imidazolidine)-derived NCN-rhodium complexes ([PhBidine-RhX2 ] and [tBu-PhBidine-RhX2 ]) were prepared by a CH insertion method, and the structures were unequivocally determined by X-ray crystallographic analysis. The [tBu-PhBidine-Rh(OAc)2 ] complex smoothly catalyzed an asymmetric Mannich reaction of malononitrile with N-Boc imines to give products in up to 94 % ee, which are useful for the synthesis of chiral α-amino acids.

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Asymmetric NH Insertion Reaction Cooperatively Catalyzed by Rhodium and Chiral Spiro Phosphoric Acids

Cited by 301 publications

References 49 publications

Mechanistic Insight into Asymmetric N–H Insertion Cooperatively Catalyzed by a Dirhodium Compound and a Spiro Chiral Phosphoric Acid

Mechanistic Insight into Asymmetric N–H Insertion Cooperatively Catalyzed by a Dirhodium Compound and a Spiro Chiral Phosphoric Acid

Cooperation of Non‐covalent Interactions and Coordination in Catalysis

Chiral Bis(imidazolidine)‐Derived NCN Pincer Rh Complex for Catalytic Asymmetric Mannich Reaction of Malononitrile with N‐Boc Imines

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