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is formed through intramolecular nucleophilic addition with release of H2O2. As an alternative pathway, the oxidation by‐product 229a, formed from the hydroperoxide 227a, can be efficiently converted into 221a under the standard reaction conditions, as proven by a control experiment.

Chemical reaction depicts the light-driven direct intramolecular C–N cross-coupling.

      Source: Modified from Jing et al. [52].

      3.4.1 Aryl C(sp2)—N Bond Formation via Radical Cross‐coupling

      Among the reported C—N bond construction methods directly from aromatic C(sp2)—H bonds and N—H bonds via radical cross‐coupling pathway, both of the coupling partners are required to be redox active to produce their corresponding radical intermediates upon oxidation. Therefore, in most cases, electron‐rich arenes such as phenols and anilines are chosen as the aryl radical precursors. As for the amine partner, electron‐rich diarylamines and azoles are commonly used. Sulfonamides after deprotonation can also turn into the corresponding radicals upon oxidation, as previously described. For these amine sources, the stabilizing effect for the N‐radicals also appears to be crucial for the success of the radical cross‐coupling.

Chemical reaction depicts the mechanistic proposal for the light-driven direct intramolecular C–N cross-coupling.

      3.4.1.1 Aryl C(sp2)—N Bond Formation Using Diarylamines

Chemical reaction depicts the visible-light-promoted CDC amination of phenols and phenothiazines. (a) Reactions with additional 2.0 equiv of TEMPO. (b) The mechanistic proposal.

      Source: Modified from Zhao et al. [53].

Chemical reaction depicts the visible-light-mediated CDC amination of phenols and acyclic diarylamines.

      Source: Modified from Zhao et al. [54].

Chemical reaction depicts the electro-oxidative para-selective C–H/N–H cross-coupling with hydrogen evolution.

      Source: Modified from Liu et al. [55].

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