A Spiro Phosphamide Catalyzed Enantioselective Proton Transfer of Ylides in a Free Carbene Insertion into N−H Bonds

Free carbene readily causes multiple side reactions due to its high energy, thus its asymmetric transformation is very difficult. We present here our findings of high‐pKa Brønsted acid catalysts that enable free carbene insertion into N−H bonds of amines to prepare chiral α‐amino acid derivatives wi...

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Published inAngewandte Chemie International Edition Vol. 62; no. 15; pp. e202300691 - n/a
Main Authors Pan, Jia‐Bin, Zhang, Xuan‐Ge, Shi, Yi‐Fan, Han, Ai‐Cui, Chen, Yu‐Jia, Ouyang, Jing, Li, Mao‐Lin, Zhou, Qi‐Lin
Format Journal Article
LanguageEnglish
Published WEINHEIM Wiley 03.04.2023
Wiley Subscription Services, Inc
EditionInternational ed. in English
Subjects
Amines
Amino acids
Asymmetric Catalysis
Brønsted Acids
Carbenes
Catalysts
Chemistry
Chemistry, Multidisciplinary
Computer applications
Enantiomers
Insertion
Intermediates
Irradiation
N−H Insertion
Organic chemistry
Phosphamides
Physical Sciences
Protons
Science & Technology
Side reactions
Bronsted Acids
PALLADIUM
Asymmetric Catalysis
ACIDITIES
ACIDS
N-H Insertion
DIAZO-COMPOUNDS
Phosphamides
Carbenes
Brønsted Acids
N−H Insertion
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Abstract Free carbene readily causes multiple side reactions due to its high energy, thus its asymmetric transformation is very difficult. We present here our findings of high‐pKa Brønsted acid catalysts that enable free carbene insertion into N−H bonds of amines to prepare chiral α‐amino acid derivatives with high enantioselectivity. Under irradiation with visible light, diazo compounds produce high‐energy free carbenes that are captured by amines to form free ylide intermediates, and then the newly designed high‐pKa Brønsted acids, chiral spiro phosphamides, promote the proton transfer of ylides to afford the products. Computational and kinetic studies uncover the principle for the rational design of proton‐transfer catalysts and explain how the catalysts accelerate this transformation and provide stereocontrol. A highly enantioselective free carbene insertion into the N−H bond of amines has been achieved. Newly designed high‐pKa Brønsted acid catalysts, chiral spiro phosphamides, were found to be key and promote the proton transfer of the ylide intermediates and control the enantioselectivity of the reaction. The reaction provides a new approach to amino acid derivatives.
AbstractList Free carbene readily causes multiple side reactions due to its high energy, thus its asymmetric transformation is very difficult. We present here our findings of high-pK(a) Bronsted acid catalysts that enable free carbene insertion into N-H bonds of amines to prepare chiral alpha-amino acid derivatives with high enantioselectivity. Under irradiation with visible light, diazo compounds produce high-energy free carbenes that are captured by amines to form free ylide intermediates, and then the newly designed high-pK(a) Bronsted acids, chiral spiro phosphamides, promote the proton transfer of ylides to afford the products. Computational and kinetic studies uncover the principle for the rational design of proton-transfer catalysts and explain how the catalysts accelerate this transformation and provide stereocontrol.
Free carbene readily causes multiple side reactions due to its high energy, thus its asymmetric transformation is very difficult. We present here our findings of high-pKa Brønsted acid catalysts that enable free carbene insertion into N-H bonds of amines to prepare chiral α-amino acid derivatives with high enantioselectivity. Under irradiation with visible light, diazo compounds produce high-energy free carbenes that are captured by amines to form free ylide intermediates, and then the newly designed high-pKa Brønsted acids, chiral spiro phosphamides, promote the proton transfer of ylides to afford the products. Computational and kinetic studies uncover the principle for the rational design of proton-transfer catalysts and explain how the catalysts accelerate this transformation and provide stereocontrol.Free carbene readily causes multiple side reactions due to its high energy, thus its asymmetric transformation is very difficult. We present here our findings of high-pKa Brønsted acid catalysts that enable free carbene insertion into N-H bonds of amines to prepare chiral α-amino acid derivatives with high enantioselectivity. Under irradiation with visible light, diazo compounds produce high-energy free carbenes that are captured by amines to form free ylide intermediates, and then the newly designed high-pKa Brønsted acids, chiral spiro phosphamides, promote the proton transfer of ylides to afford the products. Computational and kinetic studies uncover the principle for the rational design of proton-transfer catalysts and explain how the catalysts accelerate this transformation and provide stereocontrol.
Free carbene readily causes multiple side reactions due to its high energy, thus its asymmetric transformation is very difficult. We present here our findings of high-pK Brønsted acid catalysts that enable free carbene insertion into N-H bonds of amines to prepare chiral α-amino acid derivatives with high enantioselectivity. Under irradiation with visible light, diazo compounds produce high-energy free carbenes that are captured by amines to form free ylide intermediates, and then the newly designed high-pK Brønsted acids, chiral spiro phosphamides, promote the proton transfer of ylides to afford the products. Computational and kinetic studies uncover the principle for the rational design of proton-transfer catalysts and explain how the catalysts accelerate this transformation and provide stereocontrol.
Free carbene readily causes multiple side reactions due to its high energy, thus its asymmetric transformation is very difficult. We present here our findings of high‐pKa Brønsted acid catalysts that enable free carbene insertion into N−H bonds of amines to prepare chiral α‐amino acid derivatives with high enantioselectivity. Under irradiation with visible light, diazo compounds produce high‐energy free carbenes that are captured by amines to form free ylide intermediates, and then the newly designed high‐pKa Brønsted acids, chiral spiro phosphamides, promote the proton transfer of ylides to afford the products. Computational and kinetic studies uncover the principle for the rational design of proton‐transfer catalysts and explain how the catalysts accelerate this transformation and provide stereocontrol.Dedicated to the 60th anniversary of Institute of Elemento-Organic Chemistry, Nankai University.
Free carbene readily causes multiple side reactions due to its high energy, thus its asymmetric transformation is very difficult. We present here our findings of high‐p K a Brønsted acid catalysts that enable free carbene insertion into N−H bonds of amines to prepare chiral α‐amino acid derivatives with high enantioselectivity. Under irradiation with visible light, diazo compounds produce high‐energy free carbenes that are captured by amines to form free ylide intermediates, and then the newly designed high‐p K a Brønsted acids, chiral spiro phosphamides, promote the proton transfer of ylides to afford the products. Computational and kinetic studies uncover the principle for the rational design of proton‐transfer catalysts and explain how the catalysts accelerate this transformation and provide stereocontrol.
Free carbene readily causes multiple side reactions due to its high energy, thus its asymmetric transformation is very difficult. We present here our findings of high‐pKa Brønsted acid catalysts that enable free carbene insertion into N−H bonds of amines to prepare chiral α‐amino acid derivatives with high enantioselectivity. Under irradiation with visible light, diazo compounds produce high‐energy free carbenes that are captured by amines to form free ylide intermediates, and then the newly designed high‐pKa Brønsted acids, chiral spiro phosphamides, promote the proton transfer of ylides to afford the products. Computational and kinetic studies uncover the principle for the rational design of proton‐transfer catalysts and explain how the catalysts accelerate this transformation and provide stereocontrol. A highly enantioselective free carbene insertion into the N−H bond of amines has been achieved. Newly designed high‐pKa Brønsted acid catalysts, chiral spiro phosphamides, were found to be key and promote the proton transfer of the ylide intermediates and control the enantioselectivity of the reaction. The reaction provides a new approach to amino acid derivatives.
Author Han, Ai‐Cui
Chen, Yu‐Jia
Shi, Yi‐Fan
Li, Mao‐Lin
Ouyang, Jing
Zhou, Qi‐Lin
Zhang, Xuan‐Ge
Pan, Jia‐Bin
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  givenname: Xuan‐Ge
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  organization: Nankai University
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  fullname: Shi, Yi‐Fan
  organization: Nankai University
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  fullname: Han, Ai‐Cui
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  fullname: Chen, Yu‐Jia
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  givenname: Qi‐Lin
  orcidid: 0000-0002-4700-3765
  surname: Zhou
  fullname: Zhou, Qi‐Lin
  email: qlzhou@nankai.edu.cn
  organization: Nankai University
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Issue 15
Keywords Bronsted Acids
PALLADIUM
Asymmetric Catalysis
ACIDITIES
ACIDS
N-H Insertion
DIAZO-COMPOUNDS
Phosphamides
Carbenes
Brønsted Acids
N−H Insertion
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Snippet Free carbene readily causes multiple side reactions due to its high energy, thus its asymmetric transformation is very difficult. We present here our findings...
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StartPage e202300691
SubjectTerms Amines
Amino acids
Asymmetric Catalysis
Brønsted Acids
Carbenes
Catalysts
Chemistry
Chemistry, Multidisciplinary
Computer applications
Enantiomers
Insertion
Intermediates
Irradiation
N−H Insertion
Organic chemistry
Phosphamides
Physical Sciences
Protons
Science & Technology
Side reactions
Title A Spiro Phosphamide Catalyzed Enantioselective Proton Transfer of Ylides in a Free Carbene Insertion into N−H Bonds
URI https://onlinelibrary.wiley.com/doi/abs/10.1002%2Fanie.202300691
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https://www.ncbi.nlm.nih.gov/pubmed/36786065
https://www.proquest.com/docview/2791075721
https://www.proquest.com/docview/2776513131
Volume 62
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