Mechanistic Investigations of Phenoxyimine–Cobalt(II)-Catalyzed C(sp²)–C(sp³) Suzuki–Miyaura Cross-Coupling

Abstract: The mechanism of phenoxyimine (FI)−cobalt-catalyzed C(sp 2 )−C(sp 3 ) Suzuki−Miyaura cross-coupling was studied using a combination of kinetic measurements and catalytic and stoichiometric experiments. A series of dimeric (FI)cobalt(II) bromide complexes, [(4-CF 3 PhFI)CoBr] 2 , [(4-OMePhFI)CoBr] 2 , and [(2,6-di i PrPhFI)CoBr] 2 , were isolated and characterized by 1 H and 19 F NMR spectroscopies, solution and solid-state magnetic susceptibility, electron paramagnetic resonance (EPR) spectroscopy, X-ray cryst… Show more

“…1). These experiments were informed by mechanistic studies of (4‐CF 3 ‐Ph‐FI)cobalt(II)‐catalyzed C(sp 2 )–C(sp 3 ) Suzuki–Miyaura cross‐coupling, which support a “transmetalation‐first” mechanism involving the reaction of activated aryl boronate and (FI)cobalt(II) methoxide in the turnover‐limiting step [37] . Consistent with these data, a first‐order dependence on (H‐FTz)CoBr(py) 3 ( 5 a ) and a zeroth‐order dependence on alkyl bromide ( 2 a ) were obtained.…”

“…The reaction was also zeroth‐order in base‐borate complex KOMe⋅B(O i Pr) 3 , consistent with no catalyst inhibition by this reagent and highlighting a role of trialkylborates in attenuating the basicity of otherwise strong alkoxides. Previously, excess KOMe was shown to react with (FI)cobalt(II) bromide compounds to form the catalytically inactive alkoxide aggregate [KCo(OMe) 3 ] n and free K(FI) ligand [37] . Notably, the reaction also exhibited no apparent dependence on the concentration of boronic ester 1 b and is likely due to the low solubility of the activated aryl boronate ( 9 ) involved in transmetalation, which is at saturation in 2 : 1 MeCN/THF.…”

“…Previously, excess KOMe was shown to react with (FI)cobalt(II) bromide compounds to form the catalytically inactive alkoxide aggregate [KCo(OMe) 3 ] n and free K(FI) ligand. [37] Notably, the reaction also exhibited no apparent dependence on the concentration of boronic ester 1 b and is likely due to the low solubility of the activated aryl boronate (9) involved in transmetalation, which is at saturation in 2 : 1 MeCN/THF. Addition of more arylboronic ester (1 b) to the reaction mixture did not increase the amount of soluble aryl boronate (9) that participates in turnover-limiting transmetalation and a change in rate was not observed.…”

Phenoxythiazoline (FTz)‐Cobalt(II) Precatalysts Enable C(sp²)–C(sp³) Bond‐Formation for Key Intermediates in the Synthesis of Toll‐like Receptor 7/8 Antagonists**

“…1). These experiments were informed by mechanistic studies of (4‐CF 3 ‐Ph‐FI)cobalt(II)‐catalyzed C(sp 2 )–C(sp 3 ) Suzuki–Miyaura cross‐coupling, which support a “transmetalation‐first” mechanism involving the reaction of activated aryl boronate and (FI)cobalt(II) methoxide in the turnover‐limiting step [37] . Consistent with these data, a first‐order dependence on (H‐FTz)CoBr(py) 3 ( 5 a ) and a zeroth‐order dependence on alkyl bromide ( 2 a ) were obtained.…”

“…The reaction was also zeroth‐order in base‐borate complex KOMe⋅B(O i Pr) 3 , consistent with no catalyst inhibition by this reagent and highlighting a role of trialkylborates in attenuating the basicity of otherwise strong alkoxides. Previously, excess KOMe was shown to react with (FI)cobalt(II) bromide compounds to form the catalytically inactive alkoxide aggregate [KCo(OMe) 3 ] n and free K(FI) ligand [37] . Notably, the reaction also exhibited no apparent dependence on the concentration of boronic ester 1 b and is likely due to the low solubility of the activated aryl boronate ( 9 ) involved in transmetalation, which is at saturation in 2 : 1 MeCN/THF.…”

“…Previously, excess KOMe was shown to react with (FI)cobalt(II) bromide compounds to form the catalytically inactive alkoxide aggregate [KCo(OMe) 3 ] n and free K(FI) ligand. [37] Notably, the reaction also exhibited no apparent dependence on the concentration of boronic ester 1 b and is likely due to the low solubility of the activated aryl boronate (9) involved in transmetalation, which is at saturation in 2 : 1 MeCN/THF. Addition of more arylboronic ester (1 b) to the reaction mixture did not increase the amount of soluble aryl boronate (9) that participates in turnover-limiting transmetalation and a change in rate was not observed.…”

Phenoxythiazoline (FTz)‐Cobalt(II) Precatalysts Enable C(sp²)–C(sp³) Bond‐Formation for Key Intermediates in the Synthesis of Toll‐like Receptor 7/8 Antagonists**

“…Phenoxyimine (FI) cobalt complexes have proven particularly effective, and comprehensive mechanistic studies support a Co(II)-Co(III) cycle with alkyl radical intermediates derived from the electrophile (Scheme 2). [35][36][37] Here we describe kinetic and mechanistic studies that demonstrate increased rates of CÀ C bond formation with smaller N-imine substituents of the FI ligand, a consequence of accelerated rates of transmetalation. These insights led to the rational design of air-stable phenoxythiazoline (FTz)cobalt(II) precatalysts for C(sp 2 )-C(sp 3 ) Suzuki-Miyaura cross-coupling relevant to the synthesis of intermediates for TLR7/8 antagonists (Scheme 2).…”

Phenoxythiazoline (FTz)‐Cobalt(II) Precatalysts Enable C(sp²)–C(sp³) Bond‐Formation for Key Intermediates in the Synthesis of Toll‐like Receptor 7/8 Antagonists**

“…The Nakamura, Byers, , and Chirik groups independently disclosed that the well-defined iron complexes could catalyze Suzuki–Miyaura reactions of alkyl halides with arylborates or arylborons. Cobalt catalysis was recently realized for the transformation with L,X-type ligands . Notwithstanding these advances, the majority of precedents are limited by functionality tolerance and strict reaction conditions (inert atmosphere).…”

A General Copper Catalytic System for Suzuki–Miyaura Cross-Coupling of Unactivated Secondary and Primary Alkyl Halides with Arylborons