Cascade One‐Pot Synthesis of Orange‐Red‐Fluorescent Polycyclic Cinnolino[2,3‐<i>f</i>]phenanthridin‐9‐ium Salts by Palladium(II)‐Catalyzed C−H Bond Activation of 2‐Azobiaryl Compounds and Alkenes

Jayakumar, Jayachandran; Vedarethinam, Guganchandar; Hsiao, Huan‐Chang; Sun, Shang‐You; Chuang, Shih‐Ching

doi:10.1002/anie.201910959

Cited by 25 publications

(8 citation statements)

References 116 publications

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“…Without n -Bu 4 NOAc, 4a was not obtained at all, and nor was the C-H olefinated product ( 3a ) formed. Quaternary ammonium salts have always been considered to be an effective catalyst for Michael reactions [ 74 , 75 , 76 , 77 , 78 , 79 ]. As one can see from Figure 2 , the intramolecular aza-Michael reaction of ortho -alkenylated-2-phenyl-1 H -indole could indeed be improved by the addition of n -Bu 4 NOAc.…”

Section: Resultsmentioning

confidence: 99%

Rhodium-Catalyzed Oxidative Annulation of 2- or 7-Arylindoles with Alkenes/Alkynes Using Molecular Oxygen as the Sole Oxidant Enabled by Quaternary Ammonium Salt

et al. 2021

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Developing an efficient catalytic system using molecular oxygen as the oxidant for rhodium-catalyzed cross-dehydrogenative coupling remains highly desirable. Herein, rhodium-catalyzed oxidative annulation of 2- or 7-phenyl-1H-indoles with alkenes or alkynes to assemble valuable 6H-isoindolo[2,1-a]indoles, pyrrolo[3,2,1-de]phenanthridines, or indolo[2,1-a]isoquinolines using the atmospheric pressure of air as the sole oxidant enabled by quaternary ammonium salt has been accomplished. Mechanistic studies provided evidence for the fast intramolecular aza-Michael reaction and aerobic reoxidation of Rh(I)/Rh(III), facilitated by the addition of quaternary ammonium salt.

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Section: Resultsmentioning

confidence: 99%

Rhodium-Catalyzed Oxidative Annulation of 2- or 7-Arylindoles with Alkenes/Alkynes Using Molecular Oxygen as the Sole Oxidant Enabled by Quaternary Ammonium Salt

et al. 2021

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“…More recently, Chuang's group developed a palladium‐catalyzed double oxidative C−H bond activation of azobenzenes and alkenes for the construction of orange‐red‐fluorescent cinnolino[2,3‐ f ]phenanthridin‐9‐ium salts and 15 H ‐cinnolino[2,3‐ f ]phenanthridin‐9‐ium‐10‐ide (Scheme 44). [84] Interestingly, the reaction could tolerate electron rich styrene, giving the desired product in 45 % yield. However, it was not compatible with strongly electron‐deficient alkenes, such as acrylonitrile and phenyl vinyl sulfone.…”

Section: Palladium Catalysismentioning

confidence: 99%

Transition Metal‐Catalyzed Intermolecular Cascade C−H Activation/Annulation Processes for the Synthesis of Polycycles

Song

Eycken

2020

Chemistry A European J

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Polycycles are abundantly presenti nn umerous advanced chemicals, functional materials, bioactive molecules and natural products. However,t he strategies for the synthesis of polycycles are limited to classical reactions and transition metal-catalyzed cross-coupling reactions, requiring pre-functionalized starting materials and lengthy synthetic operations. The emergence of novel approaches shows great promise for the fields of organic/medicinal/materials chemistry.A mong them, transition metal-catalyzed CÀHa ctivation followed by intermolecular annulation reactions prevail, due to their straightforward manner with high atomand step-economy,p roviding rapid, concise and efficient methods for the construction of diverse polycycles. Several strategies have been developed for the synthesis of polycycles, relying on sequential multiple CÀHa ctivation/annulation, or combination of CÀHa ctivation/annulation and further interaction with ap roximal group, or merger of CÀHa ctivation with ac ycloaddition reaction, or in situ formation of the directing group. These are attractive, efficient, step-and atom-economic methods startingf rom commerciallya vailable materials. This Minireview will provide an introduction to transition metal-catalyzed CÀHa ctivation for the synthesis of polycycles, helping researchers to discoveri ndirect connections and reveal hiddeno pportunities. It will also promote the discoveryo fn ovel synthetic strategies relying on CÀHa ctivation.

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“…The main components of these energy sources are alkanes, which are also the raw materials of the chemical industry. There has been and continues to be much interest to functionalize alkanes through selective C–H bond activation to obtain more valuable organic chemicals under mild conditions. − There are many reports on C–H bond activation using transition-metal complexes. − In this area, homogeneous catalytic systems bearing late transition metals such as palladium − and platinum − are particularly important. The study of direct C–H bond activation is often difficult, and as a result, C–H alkane activation is often investigated through the protonolysis of M–C bonds (i.e., the microscopic reverse of the activation step) in organometallic compounds such as methylplatinum(II) complexes. − …”

Section: Introductionmentioning

confidence: 99%

Ligand-Controlled C_sp²–H versus C_sp³–H Bond Formation in Cycloplatinated Complexes: A Joint Experimental and Theoretical Mechanistic Investigation

et al. 2021

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The cyclometalated platinum(II) complexes [PtMe(C∧N)(L)] [1 PS : C∧N = 2-phenylpyridinate (ppy), L = SMe2; 1 BS : C∧N = benzo[h]quinolate (bhq), L = SMe2; 1 PP : C∧N = ppy, L = PPh3; and 1 BP : C∧N = bhq, L = PPh3] containing two different cyclometalated ligands and two different ancillary ligands have been investigated in the reaction with CX3CO2H (X = F or H). When L = SMe2, the Pt–Me bond rather than the Pt–C bond of the cycloplatinated complex is cleaved to give the complexes [Pt(C∧N)(CX3CO2)(SMe2)]. When L = PPh3, the selectivity of the reaction is reversed. In the reaction of [PtMe(C∧N)(PPh3)] with CF3CO2H, the Pt–C∧N bond is cleaved rather than the Pt–Me bond. The latter reaction gave [PtMe(κ1N–Hppy)(PPh3)(CF3CO2)] as an equilibrium mixture of two isomers. For L = PPh3, no reaction was observed with CH3CO2H. The reasons for this difference in selectivity for complexes 1 are computationally discussed based on the energy barrier needed for the protonolysis of the Pt–Csp 3 bond versus the Pt–Csp 2 bond. Two pathways including the direct one-step acid attack at the Pt–C bond (SE2) and stepwise oxidative–addition on the Pt(II) center followed by reductive elimination [SE(ox)] are proposed. A detailed density functional theory (DFT) study of these protonations along with experimental UV–vis kinetics suggests that a one-step electrophilic attack (SE2) at the Pt–C bond is the most likely mechanism for complexes 1, and changing the nature of the ancillary ligand can influence the selectivity in the Pt–C bond cleavage. The effect of the nature of the acid and cyclometalated ligand (C∧N) is also discussed.

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Cascade One‐Pot Synthesis of Orange‐Red‐Fluorescent Polycyclic Cinnolino[2,3‐f]phenanthridin‐9‐ium Salts by Palladium(II)‐Catalyzed C−H Bond Activation of 2‐Azobiaryl Compounds and Alkenes

Cited by 25 publications

References 116 publications

Rhodium-Catalyzed Oxidative Annulation of 2- or 7-Arylindoles with Alkenes/Alkynes Using Molecular Oxygen as the Sole Oxidant Enabled by Quaternary Ammonium Salt

Rhodium-Catalyzed Oxidative Annulation of 2- or 7-Arylindoles with Alkenes/Alkynes Using Molecular Oxygen as the Sole Oxidant Enabled by Quaternary Ammonium Salt

Transition Metal‐Catalyzed Intermolecular Cascade C−H Activation/Annulation Processes for the Synthesis of Polycycles

Ligand-Controlled C_sp²–H versus C_sp³–H Bond Formation in Cycloplatinated Complexes: A Joint Experimental and Theoretical Mechanistic Investigation

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Cascade One‐Pot Synthesis of Orange‐Red‐Fluorescent Polycyclic Cinnolino[2,3‐f]phenanthridin‐9‐ium Salts by Palladium(II)‐Catalyzed C−H Bond Activation of 2‐Azobiaryl Compounds and Alkenes

Cited by 25 publications

References 116 publications

Rhodium-Catalyzed Oxidative Annulation of 2- or 7-Arylindoles with Alkenes/Alkynes Using Molecular Oxygen as the Sole Oxidant Enabled by Quaternary Ammonium Salt

Rhodium-Catalyzed Oxidative Annulation of 2- or 7-Arylindoles with Alkenes/Alkynes Using Molecular Oxygen as the Sole Oxidant Enabled by Quaternary Ammonium Salt

Transition Metal‐Catalyzed Intermolecular Cascade C−H Activation/Annulation Processes for the Synthesis of Polycycles

Ligand-Controlled Csp2–H versus Csp3–H Bond Formation in Cycloplatinated Complexes: A Joint Experimental and Theoretical Mechanistic Investigation

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Ligand-Controlled C_sp²–H versus C_sp³–H Bond Formation in Cycloplatinated Complexes: A Joint Experimental and Theoretical Mechanistic Investigation