Alkylation of Rhodium Porphyrin Complexes with Primary Alcohols under Basic Conditions

Abstract: Primary alcohols were successfully utilized as the alkylating reagents to conveniently access rhodium porphyrin alkyl complexes in up to 91% yields under basic conditions. Mechanistic investigations suggest two possible pathways for the C–O bond cleavage: (1) nucleophilic substitution with rhodium­(I) porphyrin anion and (2) a borrowing hydrogen pathway via rhodium­(III) porphyrin hydride.

“…Previously, we reported that Rh­(ttp)­Cl could cleave the C–OH bond of benzyl alcohols and aliphatic alcohols in benzonitrile solvent under basic conditions at 120 °C to form Rh­(ttp)­Bn and Rh­(ttp)-alkyls, respectively . Considering the analogous reactivity of Ir­(por) complexes to Rh­(por) complexes in bond activation, we anticipated that the C–O bonds of various alcohols could be cleaved with Ir­(ttp)­(CO)Cl ( 1a ) under the above conditions.…”

“…Alternatively, Ir­(ttp)­OCH 2 Ph can be generated by the reaction between PhCH 2 OH ( 2a ) and Ir­(ttp)­OH from the ligand substitution of Ir­(ttp)­(CO)Cl ( 1a ) and KOH. Ir­(ttp)­OCH 2 Ph then undergoes β-H elimination with KOH to yield the Ir­(ttp) − anion and benzaldehyde. , Ir­(ttp) − can also be protonated to Ir­(ttp)H ( 1b ) by H 2 O (the p K a of Ir­(ttp)H is 15). , Subsequently, the nucleophilic Ir­(ttp) − anion attacks the carbonyl carbon in benzaldehyde to give the α-hydroxyalkyl complex Ir­(ttp)­CH­(OH)­Ph upon protonation with H 2 O. , Finally, Ir­(ttp)­CH­(OH)­Ph can be reduced by Ir­(ttp)H ( 1b ) to the desired C–O cleavage product Ir­(ttp)­CH 2 Ph ( 3a ) and Ir­(ttp)­OH, probably via σ-bond metathesis . Then, Ir­(ttp)­OH is either reused to react with PhCH 2 OH ( 2a ) or converted directly to the Ir­(ttp) − anion according to the pathway in Scheme .…”

“…In benzonitrile solvent for aliphatic alcohols, the (PhCN)Ir(ttp) − anion is formed by the solvent ligation of the Ir(ttp) − anion and serves as a nucleophile, because the (PhCN)Ir(ttp) − anion is more nucleophilic than the Ir(ttp) − anion. 10,16 ■ CONCLUSION In short, the alkylation of Ir(por)s was successfully achieved with benzyl and alkyl alcohols as the alkylating reagents. This C−O bond cleavage reaction could proceed smoothly in benzene or benzonitrile solvent under basic conditions and gave up to a 92% yield of Ir(ttp) complexes.…”

“…9,17 Finally, Ir(ttp)CH(OH)Ph can be reduced by Ir(ttp)H (1b) to the desired C−O cleavage product Ir(ttp)CH 2 Ph (3a) and Ir(ttp)OH, probably via σ-bond metathesis. 10 Then, Ir(ttp)-OH is either reused to react with PhCH 2 OH (2a) or converted directly to the Ir(ttp) − anion according to the pathway in Scheme 2. In benzonitrile solvent for aliphatic alcohols, the (PhCN)Ir(ttp) − anion is formed by the solvent ligation of the Ir(ttp) − anion and serves as a nucleophile, because the (PhCN)Ir(ttp) − anion is more nucleophilic than the Ir(ttp) − anion.…”

Base-Promoted C–O Bond Cleavage of Primary Alcohols by Iridium(III) Porphyrin Chloride

“…Previously, we reported that Rh­(ttp)­Cl could cleave the C–OH bond of benzyl alcohols and aliphatic alcohols in benzonitrile solvent under basic conditions at 120 °C to form Rh­(ttp)­Bn and Rh­(ttp)-alkyls, respectively . Considering the analogous reactivity of Ir­(por) complexes to Rh­(por) complexes in bond activation, we anticipated that the C–O bonds of various alcohols could be cleaved with Ir­(ttp)­(CO)Cl ( 1a ) under the above conditions.…”

“…Alternatively, Ir­(ttp)­OCH 2 Ph can be generated by the reaction between PhCH 2 OH ( 2a ) and Ir­(ttp)­OH from the ligand substitution of Ir­(ttp)­(CO)Cl ( 1a ) and KOH. Ir­(ttp)­OCH 2 Ph then undergoes β-H elimination with KOH to yield the Ir­(ttp) − anion and benzaldehyde. , Ir­(ttp) − can also be protonated to Ir­(ttp)H ( 1b ) by H 2 O (the p K a of Ir­(ttp)H is 15). , Subsequently, the nucleophilic Ir­(ttp) − anion attacks the carbonyl carbon in benzaldehyde to give the α-hydroxyalkyl complex Ir­(ttp)­CH­(OH)­Ph upon protonation with H 2 O. , Finally, Ir­(ttp)­CH­(OH)­Ph can be reduced by Ir­(ttp)H ( 1b ) to the desired C–O cleavage product Ir­(ttp)­CH 2 Ph ( 3a ) and Ir­(ttp)­OH, probably via σ-bond metathesis . Then, Ir­(ttp)­OH is either reused to react with PhCH 2 OH ( 2a ) or converted directly to the Ir­(ttp) − anion according to the pathway in Scheme .…”

“…In benzonitrile solvent for aliphatic alcohols, the (PhCN)Ir(ttp) − anion is formed by the solvent ligation of the Ir(ttp) − anion and serves as a nucleophile, because the (PhCN)Ir(ttp) − anion is more nucleophilic than the Ir(ttp) − anion. 10,16 ■ CONCLUSION In short, the alkylation of Ir(por)s was successfully achieved with benzyl and alkyl alcohols as the alkylating reagents. This C−O bond cleavage reaction could proceed smoothly in benzene or benzonitrile solvent under basic conditions and gave up to a 92% yield of Ir(ttp) complexes.…”

“…9,17 Finally, Ir(ttp)CH(OH)Ph can be reduced by Ir(ttp)H (1b) to the desired C−O cleavage product Ir(ttp)CH 2 Ph (3a) and Ir(ttp)OH, probably via σ-bond metathesis. 10 Then, Ir(ttp)-OH is either reused to react with PhCH 2 OH (2a) or converted directly to the Ir(ttp) − anion according to the pathway in Scheme 2. In benzonitrile solvent for aliphatic alcohols, the (PhCN)Ir(ttp) − anion is formed by the solvent ligation of the Ir(ttp) − anion and serves as a nucleophile, because the (PhCN)Ir(ttp) − anion is more nucleophilic than the Ir(ttp) − anion.…”

Base-Promoted C–O Bond Cleavage of Primary Alcohols by Iridium(III) Porphyrin Chloride

“…20,21 The Banerjee group added the nickel complex in this series in 2017. 22 Direct N-alkylation of amines with primary alcohols through the hydrogen auto-transfer reaction has been explored with rhodium-, [23][24][25] iridium-, [26][27][28][29] ruthenium-, [30][31][32][33] and osmium 34 -containing catalysts. Due to the ecological and economic benefits, it is desirable to use cheap metal-based catalysts in organic synthesis.…”

A binuclear Cu(ii) complex as an efficient photocatalyst for N-alkylation of aromatic amines

Acylation of Rhodium(III) Porphyrin Complexes with Carboxylic Acids: Scope and Mechanism