Asymmetric cation-binding catalysis

Forskning

Asymmetric cation-binding catalysis

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Standard

Asymmetric cation-binding catalysis. / Oliveira, Maria Teresa; Lee, Jiwoong.

I: ChemCatChem, Bind 9, Nr. 3, 2017, s. 377-384.

Publikation: Bidrag til tidsskrift › Tidsskriftartikel › Forskning › fagfællebedømt

Harvard

Oliveira, MT & Lee, J 2017, 'Asymmetric cation-binding catalysis', ChemCatChem, bind 9, nr. 3, s. 377-384. https://doi.org/10.1002/cctc.201601441

APA

Oliveira, M. T., & Lee, J. (2017). Asymmetric cation-binding catalysis. ChemCatChem, 9(3), 377-384. https://doi.org/10.1002/cctc.201601441

Vancouver

Oliveira MT, Lee J. Asymmetric cation-binding catalysis. ChemCatChem. 2017;9(3):377-384. https://doi.org/10.1002/cctc.201601441

Author

Oliveira, Maria Teresa ; Lee, Jiwoong. / Asymmetric cation-binding catalysis. I: ChemCatChem. 2017 ; Bind 9, Nr. 3. s. 377-384.

Bibtex

@article{1d42aadc04c44dc3ae330107bb5e090d,

title = "Asymmetric cation-binding catalysis",

abstract = "The employment of metal salts is quite limited in asymmetric catalysis, although it would provide an additional arsenal of safe and inexpensive reagents to create molecular functions with high optical purity. Cation chelation by polyethers increases the salts' solubility in conventional organic solvents, thus increasing their applicability in synthesis. The expansion of this concept to chiral polyethers led to the emergence of asymmetric cation-binding catalysis, where chiral counter anions are generated from metal salts, particularly using BINOL-based polyethers. Alkali metal salts, namely KF and KCN, are selectively bound to the catalyst, providing exceptionally high enantioselectivities for kinetic resolutions, elimination reactions (fluoride base), and Strecker synthesis (cyanide nucleophile). Asymmetric cation-binding catalysis was recently expanded to silicon-based reagents, enabling highly enantioselective silylation reactions in polyether-generated chiral environments, and leading to a record-high turnover in asymmetric organocatalysis. This can lead to further applications by the asymmetric use of other inorganic salts in various organic transformations.",

keywords = "Asymmetric catalysis, Fluoride, Polyethers, Potassium, Supramolecular chemistry",

author = "Oliveira, {Maria Teresa} and Jiwoong Lee",

year = "2017",

doi = "10.1002/cctc.201601441",

language = "English",

volume = "9",

pages = "377--384",

journal = "ChemCatChem",

issn = "1867-3880",

publisher = "Wiley - V C H Verlag GmbH & Co. KGaA",

number = "3",

}

RIS

TY - JOUR

T1 - Asymmetric cation-binding catalysis

AU - Oliveira, Maria Teresa

AU - Lee, Jiwoong

PY - 2017

Y1 - 2017

N2 - The employment of metal salts is quite limited in asymmetric catalysis, although it would provide an additional arsenal of safe and inexpensive reagents to create molecular functions with high optical purity. Cation chelation by polyethers increases the salts' solubility in conventional organic solvents, thus increasing their applicability in synthesis. The expansion of this concept to chiral polyethers led to the emergence of asymmetric cation-binding catalysis, where chiral counter anions are generated from metal salts, particularly using BINOL-based polyethers. Alkali metal salts, namely KF and KCN, are selectively bound to the catalyst, providing exceptionally high enantioselectivities for kinetic resolutions, elimination reactions (fluoride base), and Strecker synthesis (cyanide nucleophile). Asymmetric cation-binding catalysis was recently expanded to silicon-based reagents, enabling highly enantioselective silylation reactions in polyether-generated chiral environments, and leading to a record-high turnover in asymmetric organocatalysis. This can lead to further applications by the asymmetric use of other inorganic salts in various organic transformations.

AB - The employment of metal salts is quite limited in asymmetric catalysis, although it would provide an additional arsenal of safe and inexpensive reagents to create molecular functions with high optical purity. Cation chelation by polyethers increases the salts' solubility in conventional organic solvents, thus increasing their applicability in synthesis. The expansion of this concept to chiral polyethers led to the emergence of asymmetric cation-binding catalysis, where chiral counter anions are generated from metal salts, particularly using BINOL-based polyethers. Alkali metal salts, namely KF and KCN, are selectively bound to the catalyst, providing exceptionally high enantioselectivities for kinetic resolutions, elimination reactions (fluoride base), and Strecker synthesis (cyanide nucleophile). Asymmetric cation-binding catalysis was recently expanded to silicon-based reagents, enabling highly enantioselective silylation reactions in polyether-generated chiral environments, and leading to a record-high turnover in asymmetric organocatalysis. This can lead to further applications by the asymmetric use of other inorganic salts in various organic transformations.

KW - Asymmetric catalysis

KW - Fluoride

KW - Polyethers

KW - Potassium

KW - Supramolecular chemistry

U2 - 10.1002/cctc.201601441

DO - 10.1002/cctc.201601441

M3 - Journal article

AN - SCOPUS:85010379895

VL - 9

SP - 377

EP - 384

JO - ChemCatChem

JF - ChemCatChem

SN - 1867-3880

IS - 3

ER -

ID: 173020529