Substrate-selectivity stemming from recognition is a key feature of enzymes that has been seldom observed in artificial catalysts. Herein, we report a recognition-driven, substrate-selective C-H oxidation that inverts the intrinsic reactivity of the competing C-H bonds. Analysis of this selectivity highlights an unexpectedly high reactivity enhancement imparted by intramolecularity. © 2019 The Royal Society of Chemistry.
Predictability is a key requirement to encompass late-stage C-H functionalization in synthetic routes. However, prediction (and control) of reaction selectivity is usually challenging, especially for complex substrate structures and elusive transformations such as remote C(sp3 )-H oxidation, as it requires distinguishing a specific C-H bond from many others with similar reactivity.
In its minimal expression, a supramolecular catalyst that acts on a single bound substrate consists of (i) a binding unit that is complementary to a non-reacting part of the substrate, (ii) a reactive unit capable of catalyzing the reaction of the bound substrate, and (iii) a spacer connecting the two units in a geometry suitable for productive binding. When binding of two or more species is wanted, the number of binding units increases accordingly.
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