Homogeneous gold catalysis has experienced extraordinary development since the dawn of this millennium. Oxidative gold catalysis is a vibrant and fertile subfield and has over the years delivered a diverse array of versatile synthetic methods of exceptional value to synthetic practices. This review aims to cover this topic in a comprehensive manner. The discussions are organized by the mechanistic aspects of the metal oxidation states and further by the types of oxidants or oxidizing functional groups. Synthetic applications of oxidative gold catalysis are also discussed. CONTENTS 4.5. Oxidation of Sulfides and Other Functional Groups 9029 5. Conclusion and Outlook 9030 Author Information 9030 Corresponding Author 9030 Authors 9030 Author Contributions 9030 Notes 9030 Biographies 9030 Acknowledgments 9031 References 9031
By using alkanes and mercaptans as the nucleophiles with di-tert-butyl peroxide (DTBP) as the oxidant, I2-catalyzed oxidative C(sp(3))-H/S-H coupling was achieved. This protocol provides a novel process to construct C(sp(3))-S bonds from commercially available hydrocarbons and mercaptans.
Generally
applicable and stereoselective formation of 1,2-cis-glycopyranosidic linkage remains a long sought after
yet unmet goal in carbohydrate chemistry. This work advances a strategy
to this challenge via stereoinversion at the anomeric position of
1,2-trans glycosyl ester donors. This S
N
2 glycosylation is enabled under gold catalysis by
an oxazole-based directing group optimally tethered to a leaving group
and achieved under mild catalytic conditions, in mostly excellent
yields, and with good to outstanding selectivities. The strategy is
also applied to the synthesis of oligosaccharides.
A silver-catalyzed glycosylation reaction employing readily accessible and stable glycosyl ynenoates is developed. This reaction is mostly high yielding and exhibits varying levels of stereoinversion at the anomeric position. Compared to established and versatile Yu's gold catalysis, this chemistry features the use of substantially cheaper AgNTf.
By using biphenyl‐2‐ylphosphines functionalized with a remote tertiary amino group as a ligand, readily available acetylenic amides are directly converted into 2‐aminofurans devoid of any electron‐withdrawing and hence deactivating/stabilizing substituents. These highly electron‐rich furans have rarely been prepared, let alone applied in synthesis, because of their high reactivities and low stabilities associated with the electron‐rich nature of the furan ring. In this work, these reactive furans smoothly undergo either in situ intermolecular Diels–Alder reactions to deliver highly functionalized/substituted aniline products or intramolecular ones to furnish carbazole‐4‐carboxylates in mostly good to excellent yields. This work offers general and expedient access to this class of little studies electron‐rich furans and should lead to exciting opportunities for their applications.
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