Mechanistic Insights into the Effect of Sodium Iodide on Copper-Mediated Iododeboronation.

The copper-catalyzed Chan-Evans-Lam (CEL) coupling reaction advances carbon-heteroatom cross-coupling and has facilitated the development of radiohalogenation methodologies in radiochemistry. This study investigated the mechanisms and side reactions of CEL iodination under conditions relevant to radiosynthesis and typical organic synthesis, focusing on the effects of sodium iodide. The concentrations of copper and iodide, as well as the copper-to-iodide ratio, were identified as significant factors for successful copper-mediated CEL iodination, influencing the reaction mechanisms and side reactions. Excess iodide relative to the copper salt led to the formation of poorly soluble iodinated copper(I) complexes that competed with that of the desired aryl iodide. Additionally, the predominant copper complex involved in the catalytic cycle differed between the early and late stages of the reaction, depending on the copper-to-iodide ratio. The results of this study indicate that the specialized radiosynthesis conditions meet the requirements for efficient CEL iodination. In particular, an extremely low concentration of iodide is optimal for CEL iodination. These in-depth mechanistic insights not only provide a detailed comparison of CEL iodination across radiochemistry and synthetic organic chemistry but can also inspire the development of novel (radio)iodination methods.