This Letter describes the development of a Ti IIImediated reaction for the C−H amination of arenes with hydroxylamine. This reaction is applied to a variety of electronrich (hetero)arene substrates, including a series of natural products and pharmaceuticals. It offers the advantages of mild conditions (room temperature), fast reaction rates (<30 min), compatibility with ambient moisture and air, scalability, and the use of inexpensive commercial reagents.A niline derivatives (ArNH 2 ) appear in a wide variety of specialty chemicals, materials, natural products, and pharmaceuticals. 1 As such, synthetic methods for the formation of ArNH 2 are highly sought-after in organic synthesis. In general, the most common approaches involve transition-metal catalyzed cross-coupling, 2 arene nitration/reduction, 3 and arene C−H amination protocols. 4−6 However, due to high reagent/catalyst costs as well as reactivity concerns, processscale preparations of ArNH 2 still largely rely on nitration of the corresponding aromatic precursor followed by hydrogenation to yield the aniline products (Figure 1A). 7 We sought to develop a practical alternative to nitration/ reduction that enables the direct conversion of arenes (Ar−H) to ArNH 2 . Recent reports have shown that O-protected hydroxylamine derivatives (e.g., A−D in Figure 1B) are effective reagents for Fe-catalyzed arene C−H amination. 4−6 A key step of these reactions involves Fe-mediated N−O bond cleavage to release an aminyl radical (H 2 N • ). This radical (and/or its conjugate acid H 3 N •+ ) then reacts with the arene substrate, ultimately affording an aniline product. 8 While this is a conceptually attractive approach, in practice current methods are limited by the requirement for an electron-withdrawing substituent on oxygen to facilitate N−O bond scission. 9 These functionalized hydroxylamine derivatives can be expensive and/or require multistep synthesis, thus rendering them less practical for larger scale applications. Herein, we develop a method that accesses an analogous reaction manifold using the commodity chemical hydroxylamine as the aminating reagent (Figure 1C). This transformation is high yielding, inexpensive, and scalable and thus offers a complement to existing C−H amination methods as well as more traditional nitration/ reduction sequences.Pioneering early work by Keller, Kovacic, and Minisci demonstrated the feasibility of the Ti III -mediated amination of electron-rich arenes using hydroxylamine. 10−13 However, these early examples were very limited due to their narrow substrate scope, low yields, formation of side products, and the requirement for large excesses of arene substrate. 14 For
