Recent advances in enantioselective copper-catalyzed 1,4-addition

Jerphagnon, Thomas; Pizzuti, Maria Gabriella; Minnaard, Adriaan J.; Feringa, Ben L.

doi:10.1039/b816853a

Cited by 363 publications

(122 citation statements)

References 234 publications

(175 reference statements)

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“…[146,147] [111][112][113] Zu diesen Liganden gehören Derivate von Octahydro-BINOL L3, [150] TADDOLen L4, [137,151] 8,8'-verknüpften Binaphtholen L9 [152] und Spirobiindandiolen L11, [153,154] die Phosphoramidite von Zuckerphosphiten L12 [155] und 9,9'-Spirobixanthenderivate L10 [156] (Abbildung 2). Allerdings erreichten nur wenige dieser neu entwickelten Liganden in der Cu-katalysierten konjugierten Addition von Dialkylzinkreagentien an Enone die Ausbeuten und Enantioselektivitäten, die mit den früher beschriebenen Phosphoramiditen [31,32,63,112,127] (siehe Abbil- Auch die flexiblen Biphenol-Phosphoramidite L16 (siehe Abbildung 5) mit sterisch anspruchsvollen Substituenten an der Aminogruppe wurden als Liganden in der konjugierten Addition an Nitroalkene untersucht. [164] In einer ähnlichen Arbeit wurden Derivate des Biphenol-Liganden L16 mit verschiedenen Substituenten an der Biphenoleinheit eingesetzt.…”

Section: Abfangen Von Reaktionszwischenstufen Mit Elektrophilenunclassified

Phosphoramidite: privilegierte Liganden in der asymmetrischen Katalyse

2010

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Die asymmetrische Katalyse mit Übergangsmetallkomplexen ist die Grundlage unzähliger stereoselektiver Umwandlungen und hat damit das Bild der modernen Synthesechemie gewandelt. Der Schlüssel zum Erfolg war die Entwicklung chiraler Liganden zur Kontrolle der Regio‐, Diastereo‐ und Enantioselektivität. Dabei haben sich Phosphoramidite als eine äußerst vielseitige und leicht zugängliche Klasse von chiralen Liganden erwiesen. Ihre modulare Struktur ermöglicht die Herstellung von Ligandenbibliotheken und erleichtert die Feinabstimmung für eine bestimmte katalytische Reaktion. Phosphoramidite bewirken oft außerordentlich hohe Stereoselektivitäten, und ihre einzähnige Natur ist in der kombinatorischen Katalyse, die gemischte Liganden verwendet, unverzichtbar. In diesem Aufsatz werden neue Entwicklungen in der asymmetrischen Katalyse mit Phosphoramiditen diskutiert, wobei der Schwerpunkt auf der Bildung von Kohlenstoff‐ Kohlenstoff‐ und Kohlenstoff‐Heteroatom‐Bindungen liegt.

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Section: Abfangen Von Reaktionszwischenstufen Mit Elektrophilenunclassified

Phosphoramidite: privilegierte Liganden in der asymmetrischen Katalyse

2010

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“…[6] However, the relationship of the stoichiometric lithium cuprate chemistry presented in Scheme 1 to that of the catalytic Cu I /ZnMe 2 /L* systems (M = ZnMe, L* = a phosphoramidite ligand) has remained somewhat obscure. Kinetic studies of chiral copper(I)-phosphoramiditecatalyzed additions of ZnR 2 to enones are limited to early observation of a negative non-linear effect [7] and a recent study of the effect of the ligand structure on the rate by Schrader et al [8] Additional information on potential interaction modes between the CuX precatalyst and the chiral ligand were gained from comprehensive NMR studies of Gschwind et al [9] As the cuprate intermediates in Cu I /ZnMe 2 /L*-promoted reactions are very labile, we sought to harness the power of DFT-based calculations [10] to gain insight into the potential structures of p-complex C (M = MeZn, L* = phosphoramidite) in this zinc chemistry and their subsequent redox behavior.…”

Section: Introductionmentioning

confidence: 99%

Chemoselectivity as a Delineator of Cuprate Structure in Catalytic 1,4‐Addition of Diorganozinc Reagents to Michael Acceptors

Welker

Woodward

Veiros

2010

Chemistry A European J

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Reaction of the cyclic thioacetal (RS)(2)CHCHO [R=1/2 x -(CH(2))(3)-] with HCCCOMe, followed by treatment with TsCl/DABCO (Ts=tosyl, DABCO=1,4-diazabicyclo[2.2.2]octane) affords the mono-protected 1,4-benzoquinone dithioacetal. The reactivity of this SR-protected 1,4-benzoquinone has been compared with the behavior of the analogous OR-protected acetal in copper-catalyzed additions of ZnMe(2) by using chiral phosphoramidite ligands. The activation energy for 1,4-methylation of the latter OR-acetals with ZnMe(2) (>95% ee) has been determined for two CuX(2) pre-catalysts (X=OAc, 12.2 kcal mol(-1); X=OTf, 6.7 kcal mol(-1); Tf=triflate). The dithioacetal SR aromatizes in the presence of Cu(I)/ZnMe(2) giving 1,4-HOC(6)H(4)S(CH(2))(3)SMe through C-S bond formation. The disparate behavior of these two very closely related substrates is in accordance with the formation of closely related cuprate intermediates that were optimized by DFT calculations, supporting the synthetic and kinetic studies and thus defining the mechanisms of both pathways.

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“…[1] Several aspects concerning these ligands are still unclear, though. Interestingly, a number of investigations have shown that P* ligands do not always act as monodentate.…”

Section: Introductionmentioning

confidence: 99%

Secondary Interactions or Ligand Scrambling? Subtle Steric Effects Govern the Iridium(I) Coordination Chemistry of Phosphoramidite Ligands

Osswald

Rüegger

Mezzetti

2010

Chemistry A European J

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The like and unlike isomers of phosphoramidite (P*) ligands are found to react differently with iridium(I), which is a key to explaining the apparently inconsistent results obtained by us and other research groups in a variety of catalytic reactions. Thus, the unlike diastereoisomer (aR,S,S)-[IrCl(cod)(1 a)] (2 a; cod=1,5-cyclooctadiene, 1 a=(aR,S,S)-(1,1'-binaphthalene)-2,2'-diyl bis(1-phenylethyl)phosphoramidite) forms, upon chloride abstraction, the monosubstituted complex (aR,S,S)-[Ir(cod)(1,2-eta-1 a,kappaP)](+) (3 a), which contains a chelating P* ligand that features an eta(2) interaction between a dangling phenyl group and iridium. Under analogous conditions, the like analogue (aR,R,R)-1 a' gives the disubstituted species (aR,R,R)-[Ir(cod)(1 a',kappaP)(2)](+) (4 a') with monodentate P* ligands. The structure of 3 a was assessed by a combination of X-ray and NMR spectroscopic studies, which indicate that it is the configuration of the binaphthol moiety (and not that of the dangling benzyl N groups) that determines the configuration of the complex. The effect of the relative configuration of the P* ligand on its iridium(I) coordination chemistry is discussed in the context of our preliminary catalytic results and of apparently random results obtained by other groups in the iridium(I)-catalyzed asymmetric allylic alkylation of allylic acetates and in rhodium(I)-catalyzed asymmetric cycloaddition reactions. Further studies with the unlike ligand (aS,R,R)-(1,1'-binaphthalene)-2,2'-diyl bis{[1-(1-naphthalene-1-yl)ethyl]phosphoramidite} (1 b) showed a yet different coordination mode, that is, the eta(4)-arene-metal interaction in (aS,R,R)-[Ir(cod)(1,2,3,4-eta-1 b,kappaP)](+) (3 b).

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Recent advances in enantioselective copper-catalyzed 1,4-addition

Cited by 363 publications

References 234 publications

Phosphoramidite: privilegierte Liganden in der asymmetrischen Katalyse

Phosphoramidite: privilegierte Liganden in der asymmetrischen Katalyse

Chemoselectivity as a Delineator of Cuprate Structure in Catalytic 1,4‐Addition of Diorganozinc Reagents to Michael Acceptors

Secondary Interactions or Ligand Scrambling? Subtle Steric Effects Govern the Iridium(I) Coordination Chemistry of Phosphoramidite Ligands

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