Visible-light-mediated copper photocatalysis for organic syntheses

Photoredox catalysis has been applied to renewable energy and green chemistry for many years. Ruthenium and iridium, which can be used as photoredox catalysts, are expensive and scarce in nature. Thus, the further development of catalysts based on these transition metals is discouraged. Alternative photocatalysts based on copper complexes are widely investigated, because they are abundant and less expensive. This review discusses the scope and application of photoinduced copper-based catalysis along with recent progress in this field. The special features and mechanisms of copper photocatalysis and highlights of the applications of the copper complexes to photocatalysis are reported. Copper-photocatalyzed reactions, including alkene and alkyne functionalization, organic halide functionalization, and alkyl C–H functionalization that have been reported over the past 5 years, are included.


Introduction
Solar light is an inexhaustible and free energy source for green plants and bacteria. Photosynthetic organisms absorb solar energy and convert it into chemical energy via photosynthesis [1]. Photochemical reactions mimic natural photosynthesis, and photoredox catalysis plays a key role in energy-transfer processes [2][3][4][5]. Over the past decades, photoredox catalysis has attracted an increasing amount of attention [6][7][8][9], and a series of organic dyes and metal complexes have been investigated [10][11][12]. Photoredox catalysts have been initially applied to organic reactions, but they are now used for complicated organic processes [13]. As photocatalysts, organic dyes have the advantages of having a low price and not containing metals; however, they suffer from relatively poor photostability [14][15][16]. Transition-metal-photoredox catalysts, such as ruthenium and iridium polypyridyl complexes, exhibit high redox potentials, long excited state lifetimes, and strong absorption [17][18][19][20]. However, Scheme 2: Photoredox catalysis mechanism of Cu I . high cost and their scarcity discourage development of ruthenium and iridium-based catalysts [21]. Copper salts have become popular materials for photoredox catalysts due to their abundance, low cost, and ability to provide strong photoexcited reducing power [21][22][23][24]. In this review, the different catalysis mechanisms between ruthenium-based catalysts and copperbased catalysts are discussed, and the strong reduction ability of copper complexes is explained. Subsequently, mechanisms of the photoredox catalysis by Cu I and Cu II are summarized, and the copper-catalyzed reactions, including alkene functionalization, alkyne functionalization, organic halides functionalization, and alkyl C-H functionalization, are highlighted.

Review 1. Special features of photoredox-catalyzed processes by copper complexes
To understand photoredox-catalyzed processes, a discussion of the general mechanism of [Ru(bpy) 3 ] 2+ is needed [25][26][27]. When the photocatalyst Ru II is irradiated by light, an electron is transferred from the frontier metal d orbital (t 2g orbital) to the ligand-centered π* orbital (Ru II *). A metal-to-ligand charge transfer (MLCT) results in the excited singlet state. Through rapid intersystem crossing (ISC), the singlet state is transformed to the lowest-energy triplet MLCT state, which has a sufficient lifetime for initiating single-electron transfer. In the triplet species, the electron in the higher singly occupied molecular orbital (SOMO) is transferred from Ru II * to an external acceptor (A), thereby yielding oxidized Ru III , which subsequently accepts an electron from an external donor (D) to form the ground-state catalyst Ru II . This type of reaction mechanism is an oxidative quenching cycle (OQC). Alternatively, the lower energy SOMO of the excited state Ru II * can accept an electron from an external donor, which is referred to as a reductive quenching cycle (RQC; Scheme 1).
Compared with the photoredox mechanism of ruthenium-based catalysts, copper complexes show unique features [22,28]. Under irradiation, the copper complex Cu I is converted to the excited state Cu I *, which transfers electrons to an acceptor A or receives electrons from a donor D. In the OQC pathway, the excited state Cu I * transfers an electron to the acceptor A and is oxidized to Cu II . Subsequently, Cu II accepts an electron from the donor D to form the ground-state Cu I (Scheme 2). However, reports that the excited state Cu I * receives electrons from donors are relatively scarce in the literature. Thus, the RQC pathway rarely occurs for Cu I -photocatalyzed reactions. Yet, Cu I complexes have the potential to replace ruthenium or iridium-based photocatalysts in reductive photoredox reactions due to their strong reduction ability [22,29]. For example, [Cu(dap) 2 ]Cl (*Cu + /Cu 2+ = −1.43 V) provides a stronger reducing power than [Ru(bpy) 3 ]Cl (*Ru 2+ /Ru 3+ = −0.81 V) and [Ir{dF(CF 3 )ppy} 2 (dtbbpy)]Cl (*Ir 2+ /Ir 3+ = −0.89 V) [28,30]. Nevertheless, upon absorbing a photon, Cu I undergoes a reorganization from a tetrahedral geometry to a square-planar geometry, thereby resulting in a shorter excited state lifetime compared with ruthenium and iridium-based photocatalysts and thus limiting the application of Cu I complexes to visible-light-mediated organic syntheses [22,31].
Homoleptic Cu I bisphenanthroline complexes were designed with cooperative steric hindrance based on bulky substituents at the 2,9-position of the phenanthroline moiety [32,33]. Alternatively, heteroleptic Cu I complexes with phenanthroline and bulky chelating phosphine ligands were also synthesized [30,34,35]. The photophysical properties are dramatically modified by the homoleptic and heteroleptic Cu I complexes [22,31,36]. The introduction of bulky ligand substituents might efficiently prevent the reorganization of the excited state. Thus, changing the nature of the chelating ligand can improve the photostability and lifetime of the excited state to meet the requirements of a given photochemical process. The different ligands and Cu I complexes are shown in Scheme 3 [21,30]. The catalysis mechanisms of these Cu I complexes are discussed in the following sections.

Mechanisms underlying the photoredox catalysis of copper complexes
The mechanisms underlying the photoredox catalysis of Cu I complexes with different ligands were investigated by Reiser's group [21]. Other studies have since provided more information on the photoredox mechanisms underlying the catalysis of copper complexes [37]. In general, redox-active copper complexes include Cu I and Cu II complexes. The mechanisms underlying photoredox catalysis of Cu I complexes have special features and include ligand exchange and rebound mechanisms [38]. Cu II complexes provide new avenues for photoredox catal- ysis, since Cu II can undergo ligand exchange/light accelerated homolysis processes, which accelerates homolysis to produce Cu I species and radical intermediates. These intermediates can initiate productive organic transformations [39].

Visible-light-mediated Cu(I) catalytic cycle
Upon the absorption of a photon (Scheme 4), Cu I L n forms a singlet MLCT state, which subsequently yields the excited triplet state Cu I* L n via rapid ISC. The excited Cu I* L n species has a lifetime to finish the chemical processes. A radical mechanism is proposed in Scheme 4. In path a (a ligand transfer cycle), Cu I * is oxidized by an electrophilic reagent (haloalkane) to form Cu II and the radical species R • in a single-electron transfer (SET) process. Subsequently, Cu II undergoes ligand exchange with a nucleophilic reagent (Nu) to produce the Cu II −Nu species. The reorganization of Cu II -Nu is trapped by the radical intermediate R • to generate the final product (R-Nu) with concomitant regeneration of the Cu I catalyst. Alternatively, in path b (a rebound cycle), Cu I* is trapped after a SET by the radical intermediate to generate a Cu III species, which undergoes ligand exchange with the nucleophile and reductive elimination to produce the target product and the regenerated Cu I catalyst [37,38,40].

Visible-light-mediated Cu(I)-substrate catalytic cycle
Upon the irradiation of L n Cu I Nu, an electron is transferred from the metal center to the ligand, thereby generating the excited state L n Cu I Nu * . The excited state species can be oxidized by the electrophilic reagent (haloalkane, RX) to form the intermediate [L n Cu II Nu]X. The desired product Nu-R can be obtained through an inner-sphere pathway between [L n Cu II Nu]X and the radical R • [41,42] (Scheme 5A). Alternatively, a photosensitizer generated a radical via reduction or oxidation, and is not engaged in the key bond construction. [LCu I ] is photoexcited to generate L n Cu I *, which transfers an electron to the haloalkane, thereby resulting in the formation of [LCu II ]X and R • . Then, the radical R • is trapped by a second copper complex [L n Cu II Nu]X, which mediates Nu-R bond formation in an out-of-cage process (Scheme 5B).

Scheme 5:
Mechanisms of Cu I -substrate complexes.

Visible-light-mediated Cu(II) catalytic cycle
The precatalyst L n Cu II (A) undergoes ligand exchange with substrate X to form a catalytically active species, namely, L n−1 Cu II X. Upon irradiation, L n−1 Cu II X is converted to a photoexcited species L n−1 Cu II* X, which undergoes homolytic dissociation to produce L n−1 Cu I and radical X • . The radical X • can add to the substrate Y to obtain the stable radical X-Y • . Subsequently, L n−1 Cu I transfers one electron to X-Y • and accepts one ligand to regenerate the intermediate L n Cu II and the final product [39,43] (Scheme 6). Copper photocatalysis is a powerful tool that can be used to construct carbon-heteroatom and carbon-carbon bonds and can be applied to radical chemistry. This review discusses coppercatalyzed reactions including alkene and alkyne, organic halide, and alkyl C-H functionalization.

Olefinic C-H functionalization and allylic alkylation
Under mild conditions, copper salts are able to catalyze olefinic C-H functionalization or allylic alkylation, thus allow introducing alkenyl or allyl groups into organic molecules. Alkenylation and allylation reactions have been extensively investigated under thermal conditions. However, only few studies included visible-light catalysis. In 2012, Reiser's group [44] reported the allylation of α-haloketones 1 with olefins under irradiation (λ = 530 nm) in the presence of [Cu(dap) 2 Cl] (dap = 2,9-di(p-anisyl)-1,10-phenanthroline) as the catalyst. They conducted control experiments to establish that [Cu(dap) 2 Cl] and visible light are necessary for this transformation. In 2013, Ollivier and co-workers [45] successfully applied the same strategy to the allylation of diphenyliodonium 2. In 2017, Liu's group [46] reported the copper salt-catalyzed cyclization of vinyl azides 3 with ammonium thiocyanate to generate 4-alkyl/ aryl-2-aminothiazoles. Mechanistic experiments demonstrated that the photocatalyst formed in situ from Cu(OAc) 2 and ammo-nium thiocyanate promoted the intermolecular cyclization (Scheme 7).

Difunctionalization of alkenes
The 1,2-difunctionalization of alkenes is a versatile strategy for the construction of complex molecules. The primary process involved in the 1,2-difunctionalization of alkenes catalyzed by copper complexes is an atom-transfer radical addition (ATRA). Copper complexes or copper-based photoredox-active complexes formed in situ serve as photocatalysts to transfer electrons to suitable radical precursors. The detailed catalytic cycle is presented in section 3.1 and involves ligand exchange and rebound mechanisms.
A comprehensive survey of copper photocatalysts was initiated from Reiser's group. In 2015, Reiser and co-workers [47] reported the [Cu(dap) 2 ]Cl-catalyzed trifluoromethylchlorosulfonylation of unactivated alkenes 4 under photochemical conditions. When used in place of [Cu(dap) 2 ]Cl, ruthenium-based, iridium-based, and eosin Y catalysts promoted the trifluoromethylchlorination of alkenes with the extrusion of SO 2 (e.g., product 6). Studies were performed to elucidate the strikingly different reactions that occurred with these different photoredox catalysts. The catalytic cycle of [Cu(dap) 2 ]Cl is shown in Scheme 8. In this catalytic cycle, [Cu(dap) 2 ]Cl excited by irradiation with visible light reacts with triflyl chloride in a SET process to generate a trifluoromethyl radical and L n Cu II SO 2 Cl (intermediate A in Scheme 8). The formed trifluoromethyl radical adds to the alkene moiety to deliver a new alkyl radical, which is trapped by the L n Cu II -SO 2 Cl species. Free SO 2 Cldecomposes rapidly to SO 2 and Cl -. However, in this transfor-mation, SO 2 Clis stabilized by the copper complex. The alkyl radical reacts with L n Cu II -SO 2  Intrigued by this unique transformation, Reiser's group [49] extended this protocol to the chlorosulfonylation of alkenes and alkynes in 2019. Under visible light irradiation and in the presence of [Cu(dap) 2 ]Cl, the reaction of p-toluenesulfonyl chloride (7) with alkenes gave an excellent yield of the chlorosulfonylated products 8 and 9, whereas replacing the copper catalyst by ruthenium-based, iridium-based, and eosin Y catalysts afforded the desired products only in trace amount. Unexpectedly, the corresponding Cu II complex, Cu(dap)Cl 2 , also produced the desired product with good yield. Based on the literature [28,50], Cu(dap)Cl 2 acted as a potential precatalyst in this photoreaction. Upon irradiation, the Cu II complex undergoes homolytic cleavage of a Cu-Cl bond forming Cu I as the catalyt-ically active species; thus, the Cu II complex is the precatalyst and provides a more efficient transformation than Cu I . Under optimized conditions, the substrate scope was examined and determined to include activated olefins, unactivated olefins, and arylalkynes. In parallel, Hu and co-workers [51] reported the photoinduced, copper-catalyzed chlorosulfonylation of alkenes and alkynes under irradiation with blue LEDs. Reiser and co-workers [52,53] unexpectedly observed the iodoperfluoroalkylation of alkenes and perfluoroalkyl iodides 10 in the presence of [Cu(dap) 2 ]Cl. Consistent with the previous report, the desired products 11 were not obtained with rutheniumbased, iridium-based, and eosin Y catalysts (Scheme 9), which was due to the ability of copper to stabilize and interact with radical intermediates in its coordination sphere. Mechanistic studies revealed that the iodoperfluoroalkylation of alkenes and alkynes involved a rebound or ligand transfer cycle (section 3.1). In 2017, Wang and co-workers [54] discovered the photoinduced, copper-catalyzed cyanofluoroalkylation of alkenes and fluoroalkyl iodides 12. The reaction was initiated by the reduction of Cu II with tertiary amines, which formed Cu I CN and an amine radical cation [55]. Under irradiation by ultraviolet light, Cu I CN was excited and transformed to its triplet state Cu I CN * , in which the fluoroalkyl iodides were reduced to R f • and I − .
Subsequently, the radical R f • attacks the alkene forming a new alkyl radical species. This radical species is then trapped by Cu II (CN) n to generate a Cu III intermediate, which undergoes reductive elimination to form the desired product 13 (Scheme 9). In 2019, the same group [56] applied this protocol to the asymmetric cyanofluoroalkylation of alkenes. Under visible-light irradiation, the Cu-based catalyst plays a dual role as both the photosensitizer for the SET and the catalyst for asymmetric control (Scheme 9).
In addition to perfluoroalkyl iodides, this protocol was further extended to alkyl halides, trifluoromethylthiolate, amines, cycloketone oxime esters, and carboxylic acid N-hydroxyphthalimide esters (NHPI). In 2018, Peters and Fu [57] explored the copper-catalyzed three-component coupling of alkyl halides 14, olefins, and trifluoromethylthiolate 15. Mechanistic studies demonstrated that the photoexcited Cu I /binap/SCF 3 complex generated in situ engages in electron transfer with the alkyl halides, thereby providing an alkyl radical and the Cu II /binap/ SCF 3 species. Subsequently, the alkyl radical reacts with the olefin generating a new alkyl radical, which is trapped by Cu II / binap/SCF 3 to provide the coupling product (Scheme 10). In 2019, Zhang and co-workers [58] reported the photoinduced copper-catalyzed carboamination of alkenes that involved organic halides 16, alkenes, and amines 17, 18 (Scheme 10 and Scheme 11). Based on previous mechanistic studies [41], the authors found that the photoexcited ligand-Cu I −amido species transferred electrons to alkyl halides to produce alkyl radicals, Scheme 9: Chlorosulfonylation/cyanofluoroalkylation of alkenes.
which reacted with alkenes and amines to generate the threecomponent coupling products. In the absence of organic halide, the copper salts catalyzed the hydroamination of the alkene [59]. Mechanistic studies showed that the copper-amido complex coordinated with alkenes, which then acted as a primary photocatalyst. After light irradiation, the excited alkene-copper-amido species offered a benzyl radical and the organocopper via SET with hydrogen atom abstraction from CH 3 CN. Subsequently, the benzyl radical was captured by the organocopper to generate the hydroamination products (Scheme 10). In 2020, the same group [60] reported the coppercatalyzed asymmetric dual carbofunctionalization of alkenes with alkynes and alkyl halides (Scheme 11). The alkynyl copper-ligand served as the photoactive species and delivered a single electron to the alkyl halide to produce the alkyl radical, which then reacted with the alkene and alkyne to generate the coupling products (Scheme 10).
From 2018 to 2020, Xiao and Yu et al. [61,62] disclosed a series of copper-catalyzed cyanoalkylation reactions among alkenes, oxime esters, and boronic acids or alkynes. Mechanistic studies implied that the Cu I complex gets photoexcited via a SET process to generate a cyanoalkyl radical from the oxime esters. The resulting cyanoalkyl radical then adds to the alkene to form a new alkyl radical. This radical is captured by a highvalent Cu III complex, which undergoes a reductive elimination to give the target product (Scheme 12).   [72,73], the reaction is initiated by the photoirradiation of in situ-generated Cu I phenylacetylide. From the excited state of Cu I phenylacetylide an electron is transferred to the oxidants (benzoquinone or O 2 ) via a SET, thereby forming a Cu II phenylacetylide species and a radical anion. The resulting Cu II phenylacetylide species is involved in the bondforming reaction [74]. As a notable exception, in 2016, Hwang's group [75] reported the novel synthesis of unsymmetrical 1,3-conjugated diynes 31 from terminal alkynes under LED irradiation. The reaction mechanism involved a bipolar heterodimeric copper phenylacetylide species that showed similar photophysical properties (Scheme 16).

Functionalization of alkynes
In 2019, Vlla's group [76] explored the copper-catalyzed alkynylation of dihydroquinoxalin-2-ones 34 with terminal alkynes under irradiation. 4-Benzyl-3,4-dihydroquinoxalin-2(1H)-one 35 was subjected to an oxidation process with a Cu II salt to generate a nitrogen radical cation I and a Cu I species. This process regenerated Cu II in the presence of molecular oxygen. The deprotonation of the nitrogen radical cation produces an α-amino radical II, which was further oxidized to the iminium ion III to which the copper alkynylide added forming the desired product (Scheme 17).
In 2020, Zhang's group [77]  acetylide-ligand species A generated in situ was irradiated to form the activated state A * , which transferred a single electron to TCNHPI to form an alkyl radical and tetrachlorophthalimide anion and concurrently generated the oxidative Cu I acetylide species B. The intermediate B was subsequently trapped by the alkyl radical and underwent reductive elimination to deliver the desired product. Liu's group [78] further applied this protocol to the asymmetric decarboxylative alkynylation of N-hydroxy 2,3naphthalimide-derived ester 37 with terminal alkynes. Remarkably, the N-hydroxy 2,3-naphthalimide-derived ester acted as an ideal radical precursor and accepted a single electron from the excited state Cu I -acetylide complex. The copper catalyst plays a dual role, namely, as a photoredox catalyst and a cross-coupling catalyst. NHP-type esters inhibited the homodimerization of the alkyl radical and terminal alkyne (Scheme 18).
Under visible-light irradiation, disulfides are easy transformed to thiyl radicals via the homolytic cleavage of the S-S bond [79]. In 2020, Anandhan and co-workers [80]

Functionalization of organic halides
As demonstrated by the different photoredox mechanisms of Cu complexes, the Cu I complexes have strong reduction ability and can promote electron transfer to organic substrates. Thus, the high reduction potentials of Cu I complexes are also applied to the functionalization of organic halides. The seminal work by Fu and Peters demonstrated that with the help of light, copper-nucleophile complexes undergo excitation, and the resulting complex engages with organic halides in a SET process to generate alkyl or aryl radicals. Next, a C-X (X = O, N, S, C) bond is formed between the nucleophile and the alkyl or aryl radicals. From 2013 to 2019, the authors disclosed a series of nitrogen, sulfur, oxygen, and carbon nucleophiles for photoinduced, copper-catalyzed cross-couplings with organic halides. The copper-nucleophile complexes that were generated in situ as photoredox catalysts transferred electrons to organic halides, thereby achieving the cross-coupling. The detailed mechanistic studies are shown in section 3.2.
In 2013, Fu and co-workers [81] reported the photoinduced copper-catalyzed alkylation of carbazoles 41 with alkyl halides 42 and completed the corresponding mechanistic study [41,42] in 2017. This metal-catalyzed, photoinduced, and asymmetric radical transformation requires two catalysts, namely, (i) a metal catalyst that promotes electron transfer and (ii) a separate chiral catalyst that facilitates the highly stereoselective bond formation. In 2016, Fu [82] discovered the asymmetric cross-coupling of racemic tertiary alkyl halides 43 with carbazoles or indoles 44 in the Cu I /chiral phosphine system. Under irradiation conditions, excitation of the copper-nucleophile complex A results in the excited state species B that engages in the electron transfer with the alkyl halide to generate a copper II -nucleophile complex C and an alkyl radical. The formation of the R-Nu bond might occur through an in-cage pathway involving complex C (Scheme 20).
Scheme 21: C-N coupling of organic halides with amides and aliphatic amines.
In addition to carbazoles, the authors further described the C-N coupling of organic halides 45 with amides [83] and aliphatic amines [84] 46. The results of the mechanistic studies showed that a copper/tridentate carbazolide-bisphosphine ligand complex serves as a new photoredox catalyst engaged in the electron transfer to the electrophile. Under photoexcitation, the excited photoredox catalyst F reduces the alkyl halide, producing an alkyl radical and a copper II intermediate G, which oxidizes a copper I -nucleophile complex A to the corresponding copper II -nucleophile complex C. Complex C then couples with the alkyl radical to generate the product Nu-R in an outof-cage process (Scheme 21).
The same group was interested in extending this protocol from C-N bond formation reactions to C-O [85], C-S [86], and C-C [87,88] bond formations. Recently, a photoredox catalysis was applied to these types of cross-coupling reactions, with key contributions from the groups of Ackermann [87], Evano [55], Zhang [89], Nguyen [90], and Bissember [91]. In 2013, Peters' group [86] established the copper-catalyzed C-S cross-coupling between thiols and aryl halides. The mechanistic studies revealed that the reaction runs with the inexpensive precatalyst (CuI) and no ligand co-additive is necessary. In 2014, the same group [85] reported the copper-catalyzed C-O cross-coupling reaction. Results of mechanistic studies indicated that in this case a Cu I -phenoxide complex is a competent intermediate in the photoinduced C-O bond formation. In 2020, Nguyen and co-worker [90] reported copper-catalyzed C-O cross-coupling of glycosyl bromides with aliphatic alcohols. In 2015, Ackermann's group [88] disclosed the visible light-induced coppercatalyzed arylation of azoles. In this case, the mechanistic studies revealed that amino acid ligands accelerated the cross-coupling (Scheme 22).
In 2020, a visible-light-induced copper-catalyzed arylation of C(sp 2 )-H bonds of azoles was developed by Zhang [89]. heteroarenes. The cyclization of N-allyl-o-iodoanilines was further studied in intramolecular processes.

Alkyl C-H functionalization reactions
Benzylic or α-amino C-H groups and even the stable C(sp 3 )-H group were functionalized through the corresponding benzylic radical, α-amino radical, or alkyl radical. In 2016, Greaney and co-workers [92] investigated the direct C-H azidation with benzylic C-H compounds 47 and the Zhdankin reagent. After investigating a range of reaction parameters, copper salts and visible light were found to be necessary for the transformation. The reaction is highly selective for the benzylic position. In the same year, Bissember's group [93] reported a copper-photocatalyzed α-amino C-H functionalization. In this work, N,Ndialkylanilines or N-aryltetrahydroisoquinolines 48 reacted with N-substituted maleimide 49 via annulation to provide a range of tetrahydroquinolines or tetrahydroisoquinolines 50, respective-ly, with good yield. The mechanistic investigation revealed that an α-amino radical undergoes radical addition with the N-substituted maleimide (Scheme 25).
The functionalization of stable alkanes C(sp3)-H is generally difficult. In 2020, the König group [97] explored the photoinduced copper II catalyzed N-H alkylation of a broad range of nitrogen-containing compounds 61 with unactivated alkanes 62.
A tert-butoxy radical abstracted a hydrogen atom from the alkane via the photolysis of DTBP producing an alkyl radical, which reacted with nitrogen-containing compounds to give the target products 63. The catalytic cycle involves a photoinduced copper II peroxide system with an in situ-generated Cu II -N complex as the key catalytic species. In 2020, Anandhan's group [98] developed photoinduced copper-catalyzed α-C(sp 3 )-H cyclization of aliphatic alcohols with o-aminobenzamide. However, the aliphatic alcohols were limited to methanol and ethanol. In this transformation, α-C(sp 3 )-H of MeOH/EtOH undergoes a hydrogen atom transfer (HAT) process to synthesize quinazolinones involving ligand-Cu II superoxo complexes A. Under light irradiation, complex A produces the excited-state ligand-Cu II superoxo complex A*, which undergoes coordination with the aliphatic alcohol to form complex B. The latter initiates the oxidation reaction and transfers a hydrogen atom from α-C(sp 3 )-H of the alcohol to generate the Cu II hydroperoxo complex C and the corresponding aldehyde. Complex C can undergo a reductive elimination to recover 64a. The liberated aminobenzamide 64a and the aldehyde undergo a con- densation reaction to produce quinazolinone 66′, followed by oxidation with molecular oxygen to produce the desired quinazolinone 66 (Scheme 28).

Other copper-photocatalyzed reactions
With the advances in photocatalyzed reactions, radical precursors have received considerable research attention as practical and mild functional reagents. Extensive studies have been reported. The Fu [99] and Wang [100] groups reported that NHPI esters (67, 68) have been used as alkyl radical precursors in decarboxylative coupling reactions. These reactions feature a wide substrate scope. Primary, secondary, and tertiary alkyl carboxylic acids exhibit good yield, such as decarboxylative coupling reactions between N-heteroarenes 69 and redox-active esters 68. In 2018, Gong and co-workers [43] used benzyltrifluoroborates 71 as a benzylic radical source for the visible-lightinduced alkylation of imines 70. In the catalytic system, chiral ligands initiated benzylic radical formation and governed the subsequent stereoselective transformations. In addition, Fimognari's group [101] utilized copper photoredox catalysts to achieve the N-desulfonylation of benzenesulfonyl-protected N-heterocycles 72 (Scheme 29).
In 2019, Xiao's group [102] observed that under visible light or copper catalysis, cycloketone oxime esters 73 formed cyclic iminyl radicals, which then formed cyanoalkyl radicals through a selective β-C-C bond scission. This protocol was further applied to the aminocarbonylation of cycloketone oxime esters with CO gas and amines 74. Cycloketone oxime esters are reduced by the photoexcited [L n Cu I -NHR] * complex C or the ground-state L n Cu I -NHR species B to generate a cyclic iminyl radical 73a-A, which oxidizes the L n Cu II -NHR complex D (Scheme 30, path a or b). Subsequently, radical 73a-A undergoes a β-C-C bond scission to provide the cyanoalkyl radical 73a-B, which is trapped by complex D and converted to the high-valent Cu III complex E. Next, CO inserts into complex E Scheme 28: α-Amino-C-H and alkyl C-H functionalization reactions.

Scheme 29:
Other copper-photocatalyzed reactions. to generate intermediates F or G, which undergo elimination to furnish the final product 75. In 2020, Chen and co-worker [103] further explored the potential of this method and accomplished photoinduced the copper-catalyzed C(sp 3 )-O cross-coupling using oxime esters and phenols 76 (Scheme 30).
In 2020, Loh and co-workers [104] reported the copper-catalyzed highly site-selective alkylation of heteroarene N-oxides in the presence of hypervalent iodine III carboxylates. As an alkylating agent, the hypervalent iodine III carboxylates were reduced by active copper I complexes and produced an alkyl radical, which was then captured by a copper III active species. Finally, after reductive elimination, the target products were obtained (Scheme 31).

Conclusion
This review highlighted the special features and applications of photoinduced copper-catalyzed reactions. Copper photoredox catalysts are powerful photocatalysts used for cross-coupling reactions. Their function is based on the strong reducing power of copper complexes and the ability of copper complexes to coordinate substrates or trap reactive intermediates. The applications of photoinduced copper-catalyzed reactions include alkene/alkyne functionalization, organic halide functionalization, and alkyl C-H functionalization. This review introduced the photoinduced copper-catalyzed stereoselective reactions within these broad reaction categories. Copper salts coordinate with diverse chiral ligands to provide a chiral environment for asymmetric control. Despite the remarkable achievements in this field, copper-based catalytic asymmetric reactions still remain a challenging task because of the difficulty of stereocontrol of the highly reactive radical intermediates. This review discussed the fundamental mechanisms underlying copper-based photocatalysis, including Cu I /Cu II -mediated and copper substrate-mediated catalytic cycles, which are important in metallophotoredox mechanisms. The excited-state properties of Cu-based photosensitizers can be efficiently tuned by ligand modification. Although remarkable efforts have been made to elucidate and modify Cu complexes as photoredox catalysts for organic synthesis, the design of these complexes has not received much attention. If new complexes with improved redox and photophysical performances are designed, then Cu-based complexes could replace ruthenium-or iridium-based photocatalysts in the future.

Funding
We are grateful to PhD Fund (BSZ2021018) Hebei University of Chinese Medicine and scientific research plan of Hebei province universities (QN2018151) for the financial support.