Rhodaelectrocatalysis for Annulative C−H Activation: Polycyclic Aromatic Hydrocarbons through Versatile Double Electrocatalysis

Abstract: Rapid access to structurally diversified polycyclic aromatic hydrocarbons (PAHs) in ac ontrolled manner is of key significance in materials sciences.H erein, we describe as trategy featuring two distinct electrocatalytic CÀHt ransformations for the synthesis of novel nonplanar PAHs.T he combination of rhodaelectrooxidative C À Ha ctivation/ [2+ +2+ +2] alkyne annulation of easily accessible boronic acids with electrocatalytic cyclodehydrogenation provided modular access to diversely substituted PAHs with elect… Show more

“…[10] Recently,m any elegant examples of electrochemically driven transition metal catalyzed C À Hf unctionalizations have been reported, [11,12] including aPd-catalyzed C À H phosphorylation reaction [11l] and af ew Rh III -catalyzed CÀC cross-coupling reactions. [12] Herein, we describe an unprecedented Rh III -catalyzed electrochemical phosphorylation of aryl CÀHb onds that can be used to efficiently synthesize triarylphosphine oxides from diarylphosphine oxides.E xperimental results suggest that the mechanism of the C À Pb ond formation in our method involves oxidation-induced reductive elimination rather than the Rh III /Rh I catalytic cycle that has previously been proposed for similar transformations with chemical oxidants. [5] We began our studies by first optimizing electrochemical conditions for the phosphorylation of N-(2-pyridyl)aniline (1) with diphenylphosphine oxide (2), ar eaction which has not been reported previously.T he electrosynthesis was performed in an undivided cell (a three-necked round-bottomed flask) equipped with ar eticulated vitreous carbon (RVC) anode and aplatinum plate cathode.The optimal results were obtained at reflux (65 8 8C) and ac onstant current of 3mA, with areaction mixture consisting of Cp*Rh(OAc) 2 (5 mol %) as the catalyst, KPF 6 (1 equiv) as the supporting salt, and MeOH as the solvent (Table 1).…”

Scalable Rhodium(III)‐Catalyzed Aryl C−H Phosphorylation Enabled by Anodic Oxidation Induced Reductive Elimination

“…[10] Recently,m any elegant examples of electrochemically driven transition metal catalyzed C À Hf unctionalizations have been reported, [11,12] including aPd-catalyzed C À H phosphorylation reaction [11l] and af ew Rh III -catalyzed CÀC cross-coupling reactions. [12] Herein, we describe an unprecedented Rh III -catalyzed electrochemical phosphorylation of aryl CÀHb onds that can be used to efficiently synthesize triarylphosphine oxides from diarylphosphine oxides.E xperimental results suggest that the mechanism of the C À Pb ond formation in our method involves oxidation-induced reductive elimination rather than the Rh III /Rh I catalytic cycle that has previously been proposed for similar transformations with chemical oxidants. [5] We began our studies by first optimizing electrochemical conditions for the phosphorylation of N-(2-pyridyl)aniline (1) with diphenylphosphine oxide (2), ar eaction which has not been reported previously.T he electrosynthesis was performed in an undivided cell (a three-necked round-bottomed flask) equipped with ar eticulated vitreous carbon (RVC) anode and aplatinum plate cathode.The optimal results were obtained at reflux (65 8 8C) and ac onstant current of 3mA, with areaction mixture consisting of Cp*Rh(OAc) 2 (5 mol %) as the catalyst, KPF 6 (1 equiv) as the supporting salt, and MeOH as the solvent (Table 1).…”

Scalable Rhodium(III)‐Catalyzed Aryl C−H Phosphorylation Enabled by Anodic Oxidation Induced Reductive Elimination

“…With our ongoing interest in material syntheses by metalla-electrocatalysis, we have now developed a one-step electrochemical assembly of aza-PAHs via rhoda-electrocatalyzed cascade C À H annulations ( Figure 1). [12] Salient features of this electrocatalytic transformation include: a) electricity as a green oxidant, b) excellent functional group tolerance, c) three CÀH bonds activated and six new bonds formed, and d) user-friendly scale-up.…”

Electrochemical Access to Aza‐Polycyclic Aromatic Hydrocarbons: Rhoda‐Electrocatalyzed Domino Alkyne Annulations

“…Aufbauend auf unserem Interesse an der Synthese neuer Materialien durch Metallaelektrokatalyse, haben wir nun eine einstufige elektrochemische Herstellung von Aza-PAKs über Rhoda-elektrokatalytische Kaskaden-C-H-Anellierungen entwickelt (Abbildung 1). [12] Die hervorstechenden Aspekte dieser elektrokatalytischen Synthese sind: a) Strom als grünes Oxidationsmittel, b) exzellente Toleranz für funktionelle Gruppen, c) konsekutive Aktivierung von drei C-H-Bindungen und Bildung von sechs neuen Bindungen und d) benutzerfreundliche Skalierung des Reaktionsansatzes.…”

Elektrochemischer Zugang zu aza‐polycyclischen aromatischen Kohlenwasserstoffen: Rhoda‐elektrokatalytische Domino‐Alkin‐Anellierungen