α-Alkylidene-γ-butyrolactone Formation via Bi(OTf)₃-Catalyzed, Dehydrative, Ring-Opening Cyclizations of Cyclopropyl Carbinols: Understanding Substituent Effects and Predicting E/Z Selectivity

Abstract: A Bi(OTf)-catalyzed ring-opening cyclization of (hetero)aryl cyclopropyl carbinols to form α-alkylidene-γ-butyrolactones (ABLs) is reported. This transformation represents different chemoselectivity from previous reports that demonstrated formation of (hetero)aryl-fused cyclohexa-1,3-dienes upon acid-promoted cyclopropyl carbinol ring opening. ABLs are obtained in up to 89% yield with a general preference for the E-isomers. Mechanistically, Bi(OTf) serves as a stable and easy to handle precursor to TfOH. TfOH … Show more

“…6,7 Specifically we were inspired by Reisman and Jacobsen's use of thioureas to generate resonance-stabilized tricoordinate carbocations that engage in highly-selective bond-forming processes (Figure 1b). 8 The same group later showed that squaramides, combined with trimethylsilyl triflate (TMSOTf), enhance the electrophilicity of the silicon center via triflate binding. 9 Inspired by these studies, we sought to apply an analogous mode of ionization to vinyl triflates, which would provide vinyl cations capable of C-C bond-forming reactions.…”

“…Having found that urea catalyst 4 afforded the desired product in the highest yield, we next explored the effect of catalyst substitution on the product outcome. Probing monosubstituted trifluoromethyl urea catalysts (6)(7)(8) revealed the importance of a meta-trifluoromethyl group (79% yield for entry 10 vs. 3-9% yield for entries 9 and 11). Lastly, the N-methylated catalyst 9 delivered the desired product in a meager 19% yield, highlighting the importance of having both N-H hydrogenbond donors (entry 12).…”

Urea-Catalyzed Functionalization of Unactivated C–H Bonds

“…6,7 Specifically we were inspired by Reisman and Jacobsen's use of thioureas to generate resonance-stabilized tricoordinate carbocations that engage in highly-selective bond-forming processes (Figure 1b). 8 The same group later showed that squaramides, combined with trimethylsilyl triflate (TMSOTf), enhance the electrophilicity of the silicon center via triflate binding. 9 Inspired by these studies, we sought to apply an analogous mode of ionization to vinyl triflates, which would provide vinyl cations capable of C-C bond-forming reactions.…”

“…Having found that urea catalyst 4 afforded the desired product in the highest yield, we next explored the effect of catalyst substitution on the product outcome. Probing monosubstituted trifluoromethyl urea catalysts (6)(7)(8) revealed the importance of a meta-trifluoromethyl group (79% yield for entry 10 vs. 3-9% yield for entries 9 and 11). Lastly, the N-methylated catalyst 9 delivered the desired product in a meager 19% yield, highlighting the importance of having both N-H hydrogenbond donors (entry 12).…”

Urea-Catalyzed Functionalization of Unactivated C–H Bonds

“…6,7 Specifically we were inspired by Reisman and Jacobsen's use of thioureas to generate resonance-stabilized tricoordinate carbocations that engage in highly-selective bond-forming processes (Figure 1b). 8 The same group later showed that squaramides, combined with trimethylsilyl triflate (TMSOTf), enhance the electrophilicity of the silicon center via triflate binding. 9 Inspired by these studies, we sought to apply an analogous mode of ionization to vinyl triflates, which would provide vinyl cations capable of C-C bond-forming reactions.…”

“…Having found that urea catalyst 4 afforded the desired product in the highest yield, we next explored the effect of catalyst substitution on the product outcome. Probing monosubstituted trifluoromethyl urea catalysts (6)(7)(8) revealed the importance of a meta-trifluoromethyl group (79% yield for entry 10 vs. 3-9% yield for entries 9 and 11). Lastly, the N-methylated catalyst 9 delivered the desired product in a meager 19% yield, highlighting the importance of having both N-H hydrogenbond donors (entry 12).…”

Urea-Catalyzed Functionalization of Unactivated C–H Bonds

Antimony and Bismuth Complexes in Organic Synthesis