A DFT Study on the Mechanism and Origin of Regioselectivity in the Rhodium/Diene‐Catalyzed Ring‐Opening Reactions of C1‐Substituted Oxabenzonorbornadienes with Arylboronic Acids

Abstract: The mechanism and the origin of the regioselectivity of the rhodium/diene-catalyzed ring-opening reactions of C1-substituted oxabenzonorbornadienes with arylboronic acids has been examined using hybrid density functional theory (DFT). The overall mechanism for the reaction is considered as a four-step reaction including transmetalation, carborhodation, β-oxygen elimination, and protonolysis. The free energy profiles show that the rate-determining step is involved in the protonolysis step which differs from pre… Show more

“…Following migratory insertion (Figure S3), successive β-oxygen elimination will take place to give the C–O cleaved intermediate IN x 3 ( x = a–d). In our proposed mechanism, insertion of the Rh­(I) complex into the bridgehead C–O bond with retention of configuration gives the Rh­(I) alkoxide IN x 3 ( x = a–d) via a distorted five-membered-ring transition state TS x 2–3 ( x = a–d) (Figure S4), similar to that described by previously reported Rh/heterobicyclic alkenes DFT investigations. , Transition states TSa 2–3 and TSc 2–3 , where the two phenyl groups are cis to the β-oxygen, are lower in activation energy compared to TSb 2–3 and TSd 2–3 , where the two tert -butyl groups are cis to the β-oxygen. Understandably, the significant increase in energy can be accredited to the large steric hindrance from the bulky tert -butyl groups and the oxygen moiety.…”

“…On the other hand, exo attack begins with a reaction between the Rh center and the nucleophile, typically an organometallic reagent . Coordination of the Rh complex to the more accessible exo -face will result in the delivery of the nucleophile via an internal nucleophilic attack (Figure b); however, endo -selective internal nucleophilic attack has been reported (Figure c). , Recently, Pounder et al calculated the difference in activation energy for exo and endo migratory insertion of an aryl group across an bicyclic alkene using a phosphine-ligand-free Rh catalyst, suggesting that both pathways are accessible at room temperature (Figure b,c) . Nevertheless, C–O bond cleavage via the endo -carborhodated intermediates seems doubtful, as the syn -coplanar requirement of the Rh–C and C′–O bonds cannot be met for β-oxygen elimination (Figure d).…”

“…34a,b Recently, Pounder et al calculated the difference in activation energy for exo and endo migratory insertion of an aryl group across an bicyclic alkene using a phosphine-ligandfree Rh catalyst, suggesting that both pathways are accessible at room temperature (Figure 3b,c). 35 Nevertheless, C−O bond cleavage via the endo-carborhodated intermediates seems doubtful, as the syn-coplanar requirement of the Rh−C and C′−O bonds cannot be met for β-oxygen elimination (Figure 4d). Moreover, endo-carborhodated intermediates are unable to undergo β-hydride elimination, as this would produce a double bond at the bridgehead of OA, violating Bredt's rule (Figure 3d).…”

“…37 S4), similar to that described by previously reported Rh/heterobicyclic alkenes DFT investigations. 21,35 Transition states TSa 2−3 and TSc 2−3 , where the two phenyl groups are cis to the β-oxygen, are lower in activation energy compared to TSb 2−3 and TSd 2−3 , where the two tert-butyl groups are cis to the β-oxygen. Understandably, the significant increase in energy can be accredited to the large steric hindrance from the bulky tertbutyl groups and the oxygen moiety.…”

The Mechanism and Origin of Enantioselectivity in the Rhodium-Catalyzed Asymmetric Ring-Opening Reactions of Oxabicyclic Alkenes with Organoboronic Acids: A DFT Investigation

“…Following migratory insertion (Figure S3), successive β-oxygen elimination will take place to give the C–O cleaved intermediate IN x 3 ( x = a–d). In our proposed mechanism, insertion of the Rh­(I) complex into the bridgehead C–O bond with retention of configuration gives the Rh­(I) alkoxide IN x 3 ( x = a–d) via a distorted five-membered-ring transition state TS x 2–3 ( x = a–d) (Figure S4), similar to that described by previously reported Rh/heterobicyclic alkenes DFT investigations. , Transition states TSa 2–3 and TSc 2–3 , where the two phenyl groups are cis to the β-oxygen, are lower in activation energy compared to TSb 2–3 and TSd 2–3 , where the two tert -butyl groups are cis to the β-oxygen. Understandably, the significant increase in energy can be accredited to the large steric hindrance from the bulky tert -butyl groups and the oxygen moiety.…”

“…On the other hand, exo attack begins with a reaction between the Rh center and the nucleophile, typically an organometallic reagent . Coordination of the Rh complex to the more accessible exo -face will result in the delivery of the nucleophile via an internal nucleophilic attack (Figure b); however, endo -selective internal nucleophilic attack has been reported (Figure c). , Recently, Pounder et al calculated the difference in activation energy for exo and endo migratory insertion of an aryl group across an bicyclic alkene using a phosphine-ligand-free Rh catalyst, suggesting that both pathways are accessible at room temperature (Figure b,c) . Nevertheless, C–O bond cleavage via the endo -carborhodated intermediates seems doubtful, as the syn -coplanar requirement of the Rh–C and C′–O bonds cannot be met for β-oxygen elimination (Figure d).…”

“…34a,b Recently, Pounder et al calculated the difference in activation energy for exo and endo migratory insertion of an aryl group across an bicyclic alkene using a phosphine-ligandfree Rh catalyst, suggesting that both pathways are accessible at room temperature (Figure 3b,c). 35 Nevertheless, C−O bond cleavage via the endo-carborhodated intermediates seems doubtful, as the syn-coplanar requirement of the Rh−C and C′−O bonds cannot be met for β-oxygen elimination (Figure 4d). Moreover, endo-carborhodated intermediates are unable to undergo β-hydride elimination, as this would produce a double bond at the bridgehead of OA, violating Bredt's rule (Figure 3d).…”

“…37 S4), similar to that described by previously reported Rh/heterobicyclic alkenes DFT investigations. 21,35 Transition states TSa 2−3 and TSc 2−3 , where the two phenyl groups are cis to the β-oxygen, are lower in activation energy compared to TSb 2−3 and TSd 2−3 , where the two tert-butyl groups are cis to the β-oxygen. Understandably, the significant increase in energy can be accredited to the large steric hindrance from the bulky tertbutyl groups and the oxygen moiety.…”

The Mechanism and Origin of Enantioselectivity in the Rhodium-Catalyzed Asymmetric Ring-Opening Reactions of Oxabicyclic Alkenes with Organoboronic Acids: A DFT Investigation

“…Electron-donating groups (EDGs) led to naphthol compounds 9 , while electron-withdrawing groups (EWGs) led to the anticipated ring-opened 1,1,2-trisubstituted naphthalene framework 10 [ 61 ]. On the other hand, Edmunds and co-workers described a ring-opening reaction of C 1 -substituted OBDs 5 with arylboronic acids that was catalyzed by rhodium/diene to afford the 1,2,4-trisubstituted naphthalene framework 8 with complete regio- and stereocontrol ( Scheme 1 ) [ 62 – 63 ].…”

Iridium-catalyzed hydroacylation reactions of C1-substituted oxabenzonorbornadienes with salicylaldehyde: an experimental and computational study

Elucidating the Mechanism and Chemoselectivity in the PBu₃‐Catalyzed Rauhut‐Currier Reaction of Chalcone with Ethyl Acrylate