Scheme 3.18 Visible‐light‐induced direct C–H amination of heteroarenes with sulfonamides.
Source: Modified from Tong et al. [30].
In the following year, another CDC amination of heteroarenes 104 using phthalimide 105 as the N–H source was then disclosed by Itoh's group, employing 2‐tert‐butylanthraquinone (2‐t‐Bu‐AQN) as the photocatalyst and aerobic oxygen as the external oxidant (Scheme 3.19) [31]. Multiple heteroarenes are smoothly aminated under the metal‐free conditions, including diverse N‐protected indoles and pyrroles as well as benzo[b]thiophene (106a–106d). Based on several control experiments, the authors postulate that, after the deprotonation by K2CO3 and the single‐electron oxidation by the photoexcited AQN*, phthalimide 105 is converted into the key N‐centered radical 107, and the resulting AQN·− is then oxidized back to the original AQN by aerobic oxygen to complete the photocatalytic cycle. Subsequently, the desired amination product 106 is furnished from intermediate 107 after a radical addition/SET oxidation/aromatization sequence.
Scheme 3.19 Visible‐light‐mediated C–H amination of heteroarenes.
Source: Modified from Yamaguchi et al. [31].
In the same year, Itami and coworkers disclosed a CDC amination of aromatic C(sp2)–H enabled by visible light photoredox catalysis, using sulfonimides 110 as the N–H sources and a widely used Ru‐complex as the photocatalyst (Scheme 3.20) [32]. The substrate scopes of both coupling partners are reasonable, covering a variety of arylsulfonimides bearing various substituents and different arenes and heterocycles (111a–111f). The mechanism proposed by the authors is presented in Scheme 3.20b. First, the hypervalent iodine oxidant 1‐butoxy‐1λ3‐benzo[d][1,2]iodaoxol‐3(1H)‐one (IBB) undergoes a SET reduction by the photoexcited catalyst RuII* to generate a radical intermediate 112 along with a RuIII species. The subsequent single‐electron oxidation of sulfonimide 110 by RuIII yields the key imidyl radical 113, which then adds onto arene 109 to afford radical intermediate 114. Next, cationic intermediate 116 formed via a SET process between 112 and 114, further aromatizes to afford the desired amination product 111.
Scheme 3.20 Photocatalytic dehydrogenative C–H imidation of arenes with sulfonimides.
Source: Modified from Ito et al. [32].
Remarkably, aliphatic amines have also been successfully applied as aminating reagents for the CDC amination of arenes. In 2017, Nicewicz's group reported a challenging intermolecular C—N bond formation between simple arenes 117 and primary aliphatic amines 118 by means of photoredox catalysis (Scheme 3.21) [33]. This transformation, which employs a mixed solvent of 1,2‐dichloroethane (1,2‐DCE) and phosphate buffer (pH = 8), accommodates a wide range of electron‐rich aromatic and heteroaromatic compounds and diverse primary aliphatic amines including amino acids. According to fluorescence quenching experiments, both the arenes and amines are able to quench the excited photocatalyst; thus, both of their radical cations are potential reaction intermediates. However, even the less electron‐rich arenes such as benzene and toluene, which are unlikely to be oxidized by the excited photocatalyst, can undergo smooth amination to afford the corresponding aniline products (119d, 119e). Consequently, an arene radical cation pathway can be excluded in such cases. Based on all mechanistic studies, a plausible mechanism is presented by the authors as shown in Scheme 3.21b. For the reactions of electron‐poor/neutral arenes, radical cation 120 produced from SET oxidation of amine 118 by the photoexcited Mes‐Acr+* is the only possible intermediate, which subsequently adds onto arene 117 to form a cyclohexadienyl radical 121. Upon oxidation by O2 and deprotonation, 121 aromatizes to form the desired amination product 119. As for the reactions of electron‐rich arenes, both amine radical cation and arene radical cation can serve as potential intermediates, and the mechanism via the latter will be discussed in Section 3.3.
Scheme 3.21 Photocatalytic aryl C–H amination using primary aliphatic amines.
Source: Modified from Margrey et al. [33].
Organic electrochemistry has also been applied to generate N‐radicals directly from N—H bonds for addition to aromatic moieties. In 2017, Xu and coworkers described an electrochemical approach to access amidinyl radical 123 via the anodic N—H bond cleavage of substrate 122 (Scheme 3.22) [34]. Through the intramolecular cyclization of N‐radicals 123 onto their arene and heteroarene moieties, various tetracyclic benzimidazoles or pyridoimidazoles 124 are furnished with high efficiency. The reaction can also easily be scaled‐up by simply switching up the constant current (124a–124d). Additionally, substrate 122e with two potential cyclization sites is selected as an example to investigate the cyclization tendency of amidinyl radical 123e. Based on both experimental and theoretical results, 6‐endo‐trig cyclization (path a) to form a six‐membered