Nonheme iron catalyst mimics heme-dependent haloperoxidase for efficient bromination and oxidation | Science Advances

The [Fe]/H ₂ O ₂ oxidation system has found wide applications in chemistry and biology. Halogenation with this [Fe]/H ₂ O ₂ oxidation protocol and halide (X ⁻ ) in the biological system is well established with the identification of heme-iron–dependent haloperoxidases. However, mimicking such halogenation process is rarely explored for practical use in organic synthesis. Here, we report the development of a nonheme iron catalyst that mimics the heme-iron–dependent haloperoxidases to catalyze the generation of HOBr from H ₂ O ₂ /Br ⁻ with high efficiency. We discovered that a tridentate terpyridine (TPY) ligand designed for Fenton chemistry was optimal for FeBr ₃ to form a stable nonheme iron catalyst [Fe(TPY)Br ₃ ], which catalyzed arene bromination, Hunsdiecker-type decarboxylative bromination, bromolactonization, and oxidation of sulfides and thiols. Mechanistic studies revealed that Fenton chemistry ([Fe]/H ₂ O ₂ ) might operate to generate hydroxyl radical (HO ^• ), which oxidize bromide ion [Br ⁻ ] into reactive HOBr. This nonheme iron catalyst represents a biomimetic model for heme-iron–dependent haloperoxidases with potential applications in organic synthesis, drug discovery, and biology.