Yanliang Zhao

Bio: Yanliang Zhao is an academic researcher from Shandong University. The author has contributed to research in topics: Axial chirality & Carboxylate. The author has an hindex of 1, co-authored 2 publications receiving 4 citations.

Rhodium-Catalyzed C-H Activation-Based Construction of Axiall and Centrally Chiral Indenes through Two Discrete Insertions

Abstract: Reported herein is asymmetric [3+2] annulation of arylnitrones with different classes of alkynes catalyzed by chiral rhodium(III) complexes, with the nitrone acting as an electrophilic directing group. Three classes of chiral indenes/indenones have been effectively constructed, depending on the nature of the substrates. The coupling system features mild reaction conditions, excellent enantioselectivity, and high atom-economy. In particular, the coupling of N-benzylnitrones and different classes of sterically hindered alkynes afforded C-C or C-N atropochiral pentatomic biaryls with a C-centered point-chirality in excellent enantio- and diastereoselectivity (45 examples, average 95.6 % ee). These chiral center and axis are disposed in a distal fashion and they are constructed via two distinct migratory insertions that are stereo-determining and are under catalyst control.

Synthesis of Atropisomers by Transition-Metal-Catalyzed Asymmetric C-H Functionalization Reactions.

Abstract: Transition-metal-catalyzed enantioselective C-H functionalization has become a powerful strategy for the formation of C-C or C-X bonds, enabling the highly asymmetric synthesis of a wide range of enantioenriched compounds. Atropisomers are widely found in natural products and pharmaceutically relevant molecules, and have also found applications as privileged frameworks for chiral ligands and catalysts. Thus, research into asymmetric routes for the synthesis of atropisomers has garnered great interest in recent years. In this regard, transition-metal-catalyzed enantioselective C-H functionalization has emerged as an atom-economic and efficient strategy toward their synthesis. In this Perspective, the approaches for the synthesis of atropisomers by transition-metal-catalyzed asymmetric C-H functionalization reactions are summarized. The main focus here is on asymmetric catalysis via Pd, Rh, and Ir complexes, which have been the most frequently utilized catalysts among reported enantioselective C-H functionalization reactions. Finally, we discuss limitations on available protocols and give an outlook on possible future avenues of research.

Atropisomers beyond the C–C axial chirality: Advances in catalytic asymmetric synthesis

Abstract: Atropisomers beyond the C–C axis (denoted as X–Y herein) are important addition to the repertoire of axially chiral compounds, which have received much attention in recent years. Compared with conventional C–C axial chirality around biaryl and olefin axes, atropisomerism portrayed by C–N, C–O, C–B, or N–N bond was deemed to be challenging due to the relatively low rotational barriers. However, the intrinsic shorter bond length and electron-repelling effect lead to a congested hetero X–Y axis, resulting in stable axially chiral frameworks. The past two decades, especially the past few years have witnessed a rapid progress of this emerging area. A range of catalytic atroposelective approaches have been reported for the efficient synthesis of these challenging skeletons. The X–Y axially chiral compounds are valuable molecules, and they may be used as new ligands or catalysts in asymmetric catalysis or evaluated for their potential biological activities. We believe that the chemistry of atropisomers beyond C–C axial chirality will be forthcoming and blooming in the near future, taking up an important position in organic chemistry and beyond. Atropisomers beyond the C–C axis (denoted as X–Y herein) are important addition to the repertoire of axially chiral compounds, which have received much attention in recent years. Compared with conventional C–C axial chirality around biaryl and olefin axes, atropisomerism portrayed by C–N, C–O, C–B, or N–N bond was deemed to be challenging due to the relatively low rotational barriers. However, the intrinsic shorter bond length and electron-repelling effect lead to a congested hetero X–Y axis, resulting in stable axially chiral frameworks. The past two decades, especially the past few years have witnessed a rapid progress of this emerging area. A range of catalytic atroposelective approaches have been reported for the efficient synthesis of these challenging skeletons. The X–Y axially chiral compounds are valuable molecules, and they may be used as new ligands or catalysts in asymmetric catalysis or evaluated for their potential biological activities. We believe that the chemistry of atropisomers beyond C–C axial chirality will be forthcoming and blooming in the near future, taking up an important position in organic chemistry and beyond.

Stereoselective construction of atropisomers featuring a C–N chiral axis

Abstract: Atropisomeric C–N compounds belong to an important class of axially chiral compounds. However, whereas the asymmetric synthesis of biaryl atropisomers have been well established, general and efficient strategies to access single enantiomers of C–N atropisomers are still rare. Until recently, innovative methods have been developed, providing new opportunities for the highly stereoselective synthesis of this vital class of atropisomers. Herein, we comprehensively summarize the development in this emerging field and give some insights into future advance. Emphasis is placed on the synthetic strategies. Atropisomeric C–N compounds belong to an important class of axially chiral compounds. Herein, we comprehensively summarize the development in this emerging field and give some insights into future advance.

Rhodium-Catalyzed Atroposelective Access to Axially Chiral Olefins via C-H Bond Activation and Directing Group Migration

Abstract: Axially chiral open-chain olefins represent an underexplored class of chiral platform. In this report, two classes of tetrasubstituted axially chiral acyclic olefins have been accessed in excellent enantioselectivity and regioselectivity via C-H activation of (hetero)arenes assisted by a migratable directing group en route to coupling with sterically hindered alkynes. The coupling of indoles bearing an N-aminocarbonyl directing group afforded C-N axially chiral acrylamides with assistance of a racemic zinc carboxylate additive. DFT studies suggest a β-nitrogen elimination-reinsertion pathway for the directing group migration. Meanwhile, the employment of N-phenoxycarboxamide delivered C-C axially chiral enamides via migration of the oxidizing directing group. Experimental studies suggest that in both cases the (hetero)arene substrate adopts a well-defined orientation during the C-H activation, which in turn determines the disposition of alkyne in migratory insertion. Synthetic applications of representative chiral olefins have been demonstrated.

Catalytic Asymmetric Synthesis of Axially Chiral 3,3'‐Bisindoles by Direct Coupling of Indole Rings

Abstract: A new strategy for the enantioselective synthesis of axially chiral 3,3'-bisindoles was devised by the direct coupling of two indole rings. This strategy makes use of the C3-umpolung reactivity of 2-indolylmethanols, which enables the catalytic asymmetric addition reaction of 2-indolylmethanols with rationally designed 2-substituted indoles, thus constructing axially chiral 3,3'-bisindole scaffolds in overall excellent yields (up to 98%) with high enantioselectivities (up to 96 : 4 er). This approach not only has overcome the challenges in constructing axially chiral five-five-membered heterobiaryls, but also represents a new application of the C3-umpolung reactivity of 2-indolylmethanols in asymmetric catalysis. More importantly, this class of axially chiral 3,3'-bisindoles can undergo a variety of post-functionalizations to give axially chiral 3,3'-bisindole-based organocatalysts, which have found their preliminary applications in asymmetric catalysis. Appendix S1: Supporting Information Please note: The publisher is not responsible for the content or functionality of any supporting information supplied by the authors. Any queries (other than missing content) should be directed to the corresponding author for the article.