1. Introduction

Radical addition, coupling, rearrangement, and cleavage reactions are powerful in the synthesis of diverse molecular structures [1,2]. Difunctionalization reactions initiated with radical addition are attractive for both synthetic efficiency and product diversity considerations [3,4,5,6,7,8,9,10,11,12]. We have recently reported radical 1,2-difunctionalization (Scheme 1I) [13] and addition-/cyclization-based difunctionalization reactions (Scheme 1II) [14]. Compared to these two kinds of reactions, remote 1,3-, 1,4-, 1,5-, 1,6- and 1,7-difunctionalization reactions are new and under active investigation. Developments on this topic are highlighted in this paper. Most works have been published in the last five years.

In addition to traditional homolytic bond cleavage-based radical reactions induced by radical initiators or photolysis [15,16,17], other methods such as single electron transfer reagents [18,19,20,21,22], catalytic photoredox [23,24,25,26,27,28], and electrochemical reactions [29,30,31,32,33,34,35] have been developed and are gaining increasing popularity. For the remote 1,3-, 1,4-, 1,5-, 1,6- and 1,7-difunctionalization reactions presented in this paper, the initial addition of the radical X is followed by radical rearrangement through resonance, hydrogen atom transfer (HAT), group transfer, or opening of strained-rings to relocate the position of the radical. The resulting radical intermediates can couple with the radical Y to give the desired products. The radical intermediates can also be oxidized to cations, subsequently react with Y⁻ or reduced to anions, and then react with Y⁺ to give the products (Scheme 1III).

2. 1,3-Difunctionalization Reactions

Substrates used for the 1,3-difunctionalization commonly have allyl or cyclopropyl moieties. Other special substrates, such as alkynyl diazo compounds and piperidines, can be used for the reactions (Figure 1). The general reaction pathways for 1,3-difunctionalization of allyl or cyclopropyl compounds are shown in Scheme 2. The initial radical addition happens at the less hindered position of the substrate to form a stabilized radical intermediate after 1,2-group transfer or cyclopropyl ring opening, which then undergoes the second functionalization to give the product.

Studer and colleagues, in 2020, reported a method for the synthesis of 1,2,3-trisubstituted alkanes 1 using allylboronic esters as the substrates and acetylenic triflones as the reagent for 1,3-trifluoromethylacetylenic difunctionalization (Scheme 3) [36]. In the reaction process, AIBN-initiated radical leads to the formation of CF₃ radical from an alkynyl triflone which adds to the double bond of the allylboronic esters to form alkyl radicals M-1 followed by 1,2-boron migration to give more stable radicals M-2 which are trapped by acetylenic triflones to afford the products 1. This methodology can be also applied to the 1,3-trifluoromethylazido difunctionalization using trifluoromethanesulfonyl azide to give product 1d. This could also be considered as a trifunctionalization reaction since it involves the migration of the boronic ester group.

β-Alkyl nitroalkenes are good substrates for 1,3-difunctionalization. Shi and Chen group employed them in the reactions with TEMPO for the synthesis of ketones 2 bearing the vinylic alkoxyamine group (Scheme 4) [37]. In the reaction process, β-alkyl nitroalkenes are isomerized to allylic nitro compounds M-3 in the presence of a Lewis base, which are oxidized by TBHP to form radical intermediates M-4. The coupling of M-4 with TEMPO gives M-5 followed by the addition of tBuOO⁻ to form functionalized ketones 2 after NO₂ elimination.

Opening of the cyclopropane ring is a good strategy for 1,3-difunctionalization. In 2021, Lei et al., reported an electrochemical reaction of arylcyclopropanes for the synthesis of 1,3-difluorinated compounds 3 using Et₃N.3HF as a reagent for difluorination (Scheme 5) [38]. Arylcyclopropane radical cations M-6 generated from the anode oxidation of arylcyclopropanes react with a nucleophile to form radicals M-7 which are oxidized to carboniums M-8 and then react with the second nucleophiles to afford 1,3-diflourinated products 3. If alcohols or ethers are used as the nucleophiles, the reaction can produce 1,3-fluoroalkoxylated products 4a–f and 1,3-dialkoxylated products 4g–h, respectively.

Other than the allylic and cyclopropyl compounds presented above, alkynyl diazo compounds can be used for the synthesis of functionalized allenes. Zhu et al., in 2022, reported a visible-light-promoted radical reaction of alkynyl diazo compounds with RSO₂X for the synthesis of tetrasubstituted allenes 5 in high yields (Scheme 6) [39]. A proposed mechanism suggests that the sulfonyl radical adds to the α-position of the alkynyl diazo compounds to form allenyl radicals M-9 after elimination of N₂. Coupling of allenyl radicals with X radicals from RSO₂X gives 1,3-difunctionalized allenes 5 and release the sulfonyl radicals simultaneously. The resulting tetrasubstituted allenes are good substrates that can be used for cascade Michael addition/cyclization reactions for making cyclobutanone derivatives.

A unique α,γ-difunctionalization reaction of N-aryl piperidines for making bridged products was reported by Zhou et al., in 2022 (Scheme 7) [40]. In the presence of 3DPAFIPN and under blue light photocatalysis, radical M-10 generated from nitrobenzene reacts with M-11 to form iminium intermediate M-12 which is then oxidized to M-13. Base-promoted formation of N-radical M-14 from M-13 undergoes 1,5-HAT to form radical M-15 which is then coupled with the N-radical intramolecularly to give final product 6a.

The Xia and Guo group, in 2022, reported 1,3-difunctionalization of a special kind of substrates, alkyl N-hydroxyphthalimide esters, in the synthesis of γ-cyano alkenes 7 or γ,δ-unsaturated ketones 8 (Scheme 8) [41]. Under visible-light-induced photochemical conditions, alkyl radicals M-16 resulting from alkyl N-hydroxyphthalimide esters add to alkenes to form radicals M-17 which then undergo 1,5-HAT to form radicals M-18. If TMSCN is used for the reaction, radicals M-18 are converted to complex M-19 followed by reductive elimination to give γ-cyano alkenes 7. If DMSO instead of TMSCN is used for the reaction, radicals M-18 are oxidized to cations M-20 and then react with DMSO to form γ,δ-unsaturated ketones 8. It is worth noting that path A (with TMSCN) requires Cu catalyst, while path B (with DMSO) does not need Cu catalyst.

In 2020, Chu and colleagues reported a unique cyclic-oxalate-based reaction involving decarboxylative vinylation/1,5-HAT/aryl cross-coupling for the synthesis of α,γ-difunctionalized cyclohexanes 9 under photoredox and Ni dual catalysis (Scheme 9) [42]. In the reaction process, the Ir-catalyzed photoredox reaction of cyclic oxalates promotes the decarboxylation to form radicals which add to alkynes to form vinyl radicals M-21. The 1,5-HAT of M-21 followed by coupling with LNi⁰ and then with ArBr afford complexes M-22. Reductive elimination of the Ni-cat produces product 9.

3. 1,4-Difunctionalization Reactions

1,4-Difunctionalizations are more popular than 1,3-difunctionalizations. The common substrates for 1,4-difuntionalizations include 1,3-dienes, 1,3-enynes, pent-1-ynes, and isoquinolines (Figure 2). The general reaction pathways for the reaction of 1,3-dienes, 1,3-enynes, and pent-1-ynes are shown in Scheme 10. After addition of X, the position of intermediate radicals is relocated through resonance or 1,5-HAT to the 4-position for second functionalization with Y to give the 1,4-difunctionalization products.

Song and Li’s group, in 2020, reported the difunctionalization of 1,3-dienes with alkyl radicals and heterocyclics nucleophiles. The reaction of aromatic 1,3-dienes, α-carbonyl alkyl bromides and N-heterocycles in the presence of InBr₃ and Ag₂CO₃ afforded substituted N-heterocycles 10 in moderate to good yields (Scheme 11) [43]. However, the aliphatic 1,3-diene was inactive. A proposed mechanism indicated that In-coordinated alkyl radical M-23, generated from (CH₃)₂BrCO₂Et via SET of Ag₂CO₃ and the In catalyst, adds to the terminal carbon of the 1,3-diene to form ŋ³-allyl-In radical complex M-24 followed by single-electron oxidation to form cation M-25 which then reacts with heterocyclic nucleophile to afford product 10a as the major product.

A visible-light-mediated and Pd-catalyzed reaction of 1,3-dienes was reported by Glorius et al., in 2020. Under the radiation of blue LEDs and in the presence of Pd(PPh₃)₄, BINAP and KOAc in DMA, a three-component reaction of 1,3-dienes, alkyl bromides and nitrogen-, oxygen-, sulfur-, or carbon-based nucleophiles afforded products 11 in good to excellent yields (Scheme 12) [44]. The reaction mechanism suggests that hybrid alkyl Pd^I radical M-26, generated from tert-butyl bromide by photoinduced Pd catalysis, adds to the C=C bond of butadiene to form allyl Pd^I-radical complex M-27 and then Pd^II-complex M-28 after SET. The reaction of M-28 with a nucleophile followed by reductive elimination of the Pd-cat gives product 11a.

In 2021, Wang et al., reported a Ni-catalyzed three-component reaction of 1,3-butadiene with ethyl 2-bromo-2,2-difluoroacetate and arylboronic acids for the synthesis of 1,4-difluoroalkylarylated products 12 in good to excellent yields. However, ortho-substituted phenylboronic acids and cyclohexylboronic acid were found inert (Scheme 13) [45]. A proposed reaction pathway indicates that the CF₂CO₂Et radical derived from BrCF₂CO₂Et adds to the C=C bond of 1,3-butadiene to form allyl radical M-29 which reacts with ArNi^IILBr complex to form Ni^III intermediate M-30 followed by reductive elimination to give product 12a.

In 2022, Yang et al., reported a visible-light-induced and Pd-catalyzed reaction of 1,3-dienes with bromodifluoroacetamides and sulfinates or amines for the synthesis of difluorofunctionalized alkenes 13 in moderate to good yields (Scheme 14) [46]. The reaction mechanism suggests that hybrid alkyl Pd^I radical M-31, generated from BrCF₂CONHPh via a SET process by photo-induced Pd catalysis, adds to the terminal position of 1,3-butadiene to form hybrid allyl Pd^I-radical M-32 followed by SET for a Pd^II- complex which then undergoes nucleophilic addition and reductive elimination of the Pd catalyst to give product 13a.

Other than 1,4-difunction of 1,3-dienes for making substituted but-2-enes presented above, 1,3-enynes are important substrates for 1,4-difuncntion for the synthesis of substituted allenes. The key reaction process involves the resonance of propargyl radicals to allenyl radicals for the second functionalization. There are many examples reported in the literature including asymmetric synthesis under photoredox catalysts, transition metal-catalysts, and organocatalysts.

In 2009, Kambe and colleagues developed a transition metal-catalyzed reaction of 1,3-enynes, alkyl halides, and organozinc reagents for regioselective synthesis of 1,4-difunctionalized allene product 14 in moderate to good yields (Scheme 15) [47]. A proposed mechanism for 1,4-difunctionalization of 1,3-enynes indicated that the Ni(dppb) species generated from Ni(acac)₂ and organozinc reagents reacts with R₂Zn to afford Ni-complex M-33. The alkyl radical generated from the Ni-complex M-33 adds to the 1,3-enynes at the terminal position of the olefin followed by resonance to form allenyl radical intermediate M-34. The allenyl radical is trapped by (dppb)Ni^I-R complex to give Ni-complex intermediate M-35 which then undergoes reductive elimination to afford allene product 14.

In 2019, Wang et al., reported a method for the synthesis of 1,4-fluoroalkylated allenes 15 via a Ni-catalyzed reaction of 1,3-enynes under mild conditions (Scheme 16) [48]. In the reaction process, the arylated Ni^I species M-36 generated through the transmetallation of the Ni^I catalyst with aryl boronic acid reduces the fluoroalkyl bromide to afford fluoroalkyl radical M-37 and Ni^II complex M-38. The capture of fluoroalkyl radical M-37 by a 1,3-enyne followed by 1,3-radical shift generates the key intermediate allenyl radical M-39, which then coordinates with Ni^II complex M-38 to afford oxidized Ni^III complex M-40. At the last step, reductive elimination of Ni^III complex 6 gives the tetrasubstituted allene product 15.

In 2019, Ma et al., reported a Cu-catalyzed atom transfer radical addition of aryl sulfonyl iodides to 1,3-enynes for the synthesis of allenyl iodides 16 under mild conditions (Scheme 17) [49]. A suggested reaction mechanism indicates that the aryl sulfonyl radicals (ArSO₂·) generated from aryl sulfonyl iodides adds to the alkene moiety of 1,3-enynes to afford allenyl radical M-41. Trapping of the radicals M-41 with LCuI₂ produces allenyl Cu^III diiodide species M-42 which lead to the formation of allenyl iodides 16 after reductive elimination of the catalyst.

Recently, Lv and colleagues developed a Cu-catalyzed 1,4-sulfonylcyanation reaction of 1,3-enynes with alkyl or aryl sulfonyl chlorides and TMSCN (Scheme 18) [50]. Under the catalysis of Cu(CH₃CN)₄PF₆, sulfonyl-containing allenic nitriles 17 were obtained in good yields and high regioselectivity. A reaction mechanism suggests that the sulfonyl radicals generated from sulfonyl chlorides and LCu^I species adds to the alkene moiety of 1,3-enynes to afford allenyl radicals M-43 followed by the coordination with LCu^IICl and ligand exchange with TMSCN to give cyano-Cu^III species M-44. Sulfonyl-containing allenyl nitrile products 17 are obtained after the reductive elimination of the Cu-catalyst. Lv et al., also developed a 1,4-sulfonyliodination reaction of 1,3-enynes to synthesize a tetrasubstituted allenyl iodides 18 under metal-free conditions (Scheme 19) [51]. The reaction of 1,3-enynes with sulfonyl hydrazides and I₂ in the presence of tert-butyl hydroperoxide (TBHP) at room temperature gave the allenyl iodide products in satisfactory yields with excellent regioselectivity and good functional group tolerance. In 2022, Li and Wang’s group disclosed a visible-light-induced and Ni-catalyzed 1,4-arylsulfonation of 2-methyl-1,3-enynes to synthesize compounds 19 (Scheme 20) [52].

A number of Cu-catalyzed and Togni’s reagent-based trifluomethylation reactions have been reported. In 2018, Liu et al., reported a tunable 1,2- and 1,4-addition of 1,3-enynes for the synthesis of CF₃-containing tri- and tetrasubstituted allenyl nitriles (Scheme 21) [53]. The Cu-catalyzed reaction of 1,3-enynes with Togni’s reagent and TMSCN in the presence of Cu(CH₃CN)₄PF₆ under nitrogen atmosphere gave 1,2-/1,4-addition allenyl nitriles (20/21) in moderate to excellent yield. The regioselectivity could be controlled by using different ligands. The reactions using phenanthroline-type ligand L1 primary gave 1,4-addition allenyl nitriles product 20 through an allenyl-Cu^III species Int-I. The reactions using bisoxazoline ligands L2 in the presence of Et₃N produced 1,2-propargylic cyanation products 21 via the Int-II complex intermediates. It is worth noting that, the reactions of 1,3-enynes with R² at C2 position only afforded 1,4-addition product 20c due to the steric hindrance at C2 position which prevents the interaction of the tertiary propargyl radical with the reactive Cu^II cyanide complex. In 2020, the Li group reported a Cu-catalyzed reaction of 1,3-enynes with Togni II reagent and (bpy)Zn(CF₃)₂ for the synthesis of 1,4-bis(trifluoromethylated) allenes 22 (Scheme 22) [54].

Yang and colleagues, in 2021, extended the reaction scope for the synthesis CF₃-containing tetrasubstituted allenes. They reported a Cu-catalyzed 1,4-difunctionalization reaction of 1,3-enynes with Togni II reagent and a nucleophilic halide reagent (SOX₂) (Scheme 23) [55]. In the reaction process, a CF₃ radical generated from Togni II adds to the 1,3-enynes to afford allenyl radical intermediates M-45 followed by the combination with Cu^II and SOCl₂ to give a CF₃-allenyl-Cu^IIICl₂ species M-46. Reductive elimination of the Cu-cat gives 1,4-halotrifluormethylation product 23.

The Yang and Cao group, in 2023, reported a Cu-catalyzed ATRA reaction of 1,3-enynes with Togni II reagent for making trifluoromethylbenzoxylated allenes 24 (Scheme 24) [56]. The Togni II reagent plays triple roles in the reaction process, including the source of CF₃ radical, the nucleophile for the second functionalization, and an oxidant for Cu catalysis. It is worth noting that 1,3-enynes bearing the fully substituted alkene moiety were employed to disfavor the radical addition to the alkene moiety at the initiate step. Thus, in this reaction system, CF₃ radical attacks the alkyne position of 1,3-enynes to generate trifluoromethyl-substituted allenyl radical M-47 which are oxidized to cations M-48 followed by nucleophilic addition to form product 24. The products can be readily converted to corresponding allenols 25.

In 2021, Ma et al., introduced a Cu-catalyzed 1,4-addition of 1,3-enynes with cyclobutanone oxime esters and TMSCN to give allene products 26 in moderate to good yields (Scheme 25) [57]. A reaction mechanism suggests that the Cu^I species reacts with cyclobutanone oxime ester to give the cyanoalkyl radical M-49 and Cu^II species M-50 via a SET process. Radical M-49 adds to the C=C bond of 1,3-enynes to afford allenyl radicals M-51. In another path, intermediate M-52, which is generated by ligand exchange of M-50 with TMSCN, couples with allenyl radicals M-51 to produce allenyl Cu^III complex M-53. Subsequential reductive elimination of LCu^IIIBr affords 1,4-carbocycanated allene products 26. If TMSCF₃ is used to replace TMSCN as a nucleophile, the reactions give 1,4-carbotrifluoromethylated allene products.

Wu and colleagues, in 2021, disclosed a Cu-catalyzed reaction of 1,3-enynes to give cyanoalkylsulfonylated allenyl selenides products 27 (Scheme 26) [58]. The reaction of 1,3-enynes, diselenides, DABCO·(SO₂)₂ and cycloketone oxime esters under the catalysis of CuOAc without ligand gave products 27 in good yields. A reaction mechanism suggests that the iminyl radicals generated from cycloketone oxime esters undergoes β-C–C bond cleavage to give cyanoalkyl radical M-54 which then is captured by SO₂ from DABCO·(SO₂)₂ to generate cyanoalkylsulfonyl radical M-55. The addition of radical M-55 to 1,3-enynes at the terminal C=C bond carbon affords propargyl radical which is converted to allenyl radical M-56 through resonance. The coordination of M-56 with Cu^I specie gives Cu^II complex M-57 followed by the interaction with diphenyl diselenide to afford Cu^III complex M-58 and a phenyl seleno radical. Subsequent reductive elimination of Cu^III affords product 27a.

The vinyl enynes are good substrates for 1,4-difunctionalization. In 2021, Wu et al., reported a visible-light-induced 1,4-hydroxysulfonylation of vinyl enynes for the synthesis of sulfonyl allenic alcohols [59]. The reaction of diarylterminated enynes and aryl or alkyl sulfonyl chlorides in the presence of fac-Ir(ppy)₃ and K₃PO₄ under the radiation of blue LEDs afforded 1,4-hydroxysulfonyl allenes 28 in good to excellent yields (Scheme 27). However, the action with trifluoromethanesulfonyl chloride for 28e was ineffective. A reaction mechanism suggests that the hydroxyl radical generated from water via the HAT with chloride radical adds to the C=C bond of diarylterminated enyne to form the propargyl radical followed by tautomerization to the allenic radical M-59 which couples with the sulfonyl radical to give product 28a.

Wu et al., in 2022, reported a metal-free radical difunctionalization reaction of vinyl enynes with NBS to afford diverse 4-bromo-allenic alcohols 29 in good yields (Scheme 28) [60]. In the reaction process, hydroxyl radical derived from H₂O adds to the C=C bond and then traps bromo radicals generated from NBS to give products 29.

N-Hydroxyphthalimide (NHP) esters are good precursors for generating alkyl radicals. In 2021, Lu et al., reported a photoredox and Cu-catalysis reaction for 1,4-carbocyanation of 1,3-enynes (Scheme 29) [61]. The reaction of 1,3-enynes with N-hydroxyphthalimide (NHP) esters and TMSCN under Cu/photoredox dual catalysis gave tetrasubstituted allenes 30 in good yields and excellent functional group tolerance. A reaction mechanism suggests that the excited state Ir^III* generated from photocatalyst Ir(ppy)₃ reacts with the NHP esters through a SET process to give ester radical anions M-60 which undergo decarboxylation to form alkyl radicals R³·. The subsequent alkyl radical addition to C=C double bond of 1,3-enynes affords allenyl radical M-61 which coordinates with TMSCN to create cynanocopper^III species M-62. At the last step, reductive elimination of the Cu-catalyst affords tetrasubstituted allenic nitriles 30.

There are several reports on dual Ni/photoredox catalyzed reactions for 1,4-difunctionalizations. Lu et al., reported 1,4-sulfonylarylation of 1,3-enynes for the synthesis of allenes 31 (Scheme 30) [62]. In the presence of NiCl₂·glyme, diOMebpy ligand, organic photosensitizer (1,2,3,5-tetrakis(carbazol-9-yl)-4,6-dicyanobenzene) (4CzIPN), the reaction of 1,3-enynes with sodium sulfinates as radical precursors and aryl halides as coupling partners afforded sulfone-containing allenes 31 in fair to good yields. A reaction mechanism suggests that the excitation of photocatalyst (PC) 4CzIPN leads to the activated M-63 which then reacts with R³SO₃Na to form sulfonyl radical R³SO₂· along with the reduced state PC M-64. The addition of sulfonyl radicals to the alkene moiety of 1,3-enynes affords allenyl radicals M-65 which then convert to allenyl Ni^I species M-66 after interception with LNi⁰. Oxidative addition of aryl halides to M-66 creating the allenyl Ni^III intermediates M-67 which undergo reductive elimination to give sulfone-containing allenes 31. The Li and Wang groups also reported the 1,4-sulfonylarylation of 1,3-enynes [63,64].

In 2022, the Kong and Wang groups introduced a photoredox reaction for dicarbonation of trifluoromethylated 1,3-enynes (Scheme 31) [65]. In the presence of TBADT and Ni(dibbpy)Br₂ catalysts and under near-ultraviolet light irradiation, the reaction of 1,3-enynes with alkanes and alkyl halides afforded tetrasubstituted CF₃-allenes 32. A reaction mechanism suggests that the cyclohexyl radical generated by the photoredox catalysis adds to the alkene moiety of 1,3-enyne to give allenyl radical M-68 which reacts with M-69 to form Ni-complex M-70 followed by a Ni shift to give more stable allenyl-Ni^I complex M-71. The subsequent oxidative addition of ethyl 4-bromobenzoate to M-71 gives allenyl-Ni^III intermediate M-72 which gives product 32a after reductive elimination of LNi^IIIBr.

In 2021, Du et al., introduced an N-heterocyclic carbene (NHC) organocatalyzed reaction for 1,4-alkylcarbonylation of 1,3-enynes 33 (Scheme 32) [66]. The reaction of 1,3-enynes with alkyl radical precursors and aldehydes under NHC organocatalysis gave allenyl ketone products 33 in moderate to excellent yields. A reaction mechanism suggests that the reaction of an aldehyde and NHC M-73 under a basic condition gives Breslow intermediates M-74 which interact with CF₃I to afford a CF₃ radical and NHC-bound ketyl radicals M-75. The addition of CF₃ radical to the C=C double bond of 1,3-enynes gives allenyl radicals M-76 which are coupled with ketyl radicals M-75 to give NHC-allenyl intermediates M-77. The final allenyl ketone products 33 are generated from M-77 after elimination of NHC. Recently, Du et al., applied a similar reaction for making gem-difluorovinylcarbonylated allenes 34 (Scheme 33) [67]. The Huang and Yang groups also reported this kind of reactions for the synthesis of 1,4-alkylcarbonylated allenes 35 (Scheme 34) [68,69]. In 2022, the Zhang and Zheng’s group reported a reaction which combined the NHC and photoredox catalysis for 1,4-sulfonylacylation of 1,3-enynes. The reaction of 1,3-enynes, aroyl fluorides, and sodium sulfinates under blue light irradiation affords sulfone-containing allenyl ketones 36 in moderate to good yields (Scheme 35) [70].

In 2019, Bao et al., reported a Cu-catalyzed 1,4-alkylarylation of 1,3-enynes using diacyl peroxide as radical precursors and aryl boronic acids as nucleophiles to afford tetrasubstituted allenes 37 in moderate to good yields (Scheme 36) [71]. In the reaction process, LCu^II-Ar complexes M-78 and alkyl radicals are resulting from (RCO₂)₂. The alkyl radicals add to 1,3-enynes to form allenyl radicals M-79 which then react with M-78 in two possible ways. In path a, the radicals M-79 couple with M-78 to form tetrasubstituted allene products 37 and regenerate the LCu^I catalyst. While in path b, the coordination of M-79 with M-78 afford Cu^III species M-80 which then give product 37 after reductive elimination of LCu^I catalyst.

Bao et al., in 2019, reported another Cu-catalyzed reaction for 1,4-alkylcyanation, 1,4-fluoroalkylcyanation and 1,4-sulfimidocyanation of 1,3-enynes (Scheme 37) [72]. The reaction of 1,3-enynes with TMSCN and various radical precursor reagents (alkyl diacyl peroxides, fluoroalkylated iodides and N-fluorobenzenesulfonimide) afforded corresponding allenyl nitriles compounds 38 as racemic compounds in moderate to good yield and high regioselectivity. The proposed reaction mechanism is different from the Cu^III mechanism in the cyanation reactions reported previously. In this case, the alkyl radical generated from diacyl peroxide add to 1,3-enynes to form allenyl radicals M-81 which then couple with isocyanocopper species M-82 to form complexes M-83. Reductive elimination of LCu^II catalyst from M-83 affords substituted allenyl nitriles 38. In 2020, Bao et al., employed the use of a chiral ligand for asymmetric 1,4-difunctionalization of 1,3-enynes in the synthesis of 39 (Scheme 38) [73].

Organocatalysts can be used for asymmetric 1,4-carboalkynylation of 1,3-enyne. Liu et al., in 2019, reported a Cu and cinchona alkaloid-derived catalytic system for the reaction of 1,3-enynes with alkyl halides and alkynes to give 1,4-carboalkynylation products 40 in moderate to good yields with the high ee ratio (Scheme 39) [74]. A reaction mechanism suggests that complex M-84, generated from the reaction of Cu^IX, ligand and alkynes under basic conditions, reacts with alkyl halides to form Cu^II species M-85 and R³ alkyl radicals. The alkyl radicals add to the 1,3-enynes to form allenyl radicals M-86 then couple with M-84 to afford chiral tetrasubstituted allenes 40. In this reaction, the chiral cinchona alkaloid-derived N,N,P-complex is the key for the enantiocontrol during the reaction with highly reactive allenyl radical M-86.

Wang et al., in 2022, reported an asymmetric 1,4-difunctionalization of 1,3-enynes using dual photoredox and Cr catalysts. The reaction of 1,3-enynes with aldehydes and DHP esters in the presence of CrCl₂, 4CzIPN and chiral ligand under the radiation of blue LEDs afforded chiral allenols 41 in moderate to good yields with high enantioselectivities (Scheme 40) [75]. The reaction mechanism suggests that isopropyl radical generated from DHP ester assisted adds to 1,3-enyne to provide propargyl radical M-87 followed by trapping with Cr^IIL to form the propargyl chromium M-88 and then chiral intermediate M-89 after nucleophilic addition to benzaldehyde. A six-member cyclic transition state controls the enantioselectivity for the Nozaki–Hiyama allenylation [76]. The final product 41a is then obtained after the protonation of M-89.

Highly strained alkylidenecyclopropanes (ACPs) are useful structure moieties in organic synthesis. Sequential 6π-electrocyclization and vinylcyclopropane rearrangement of allene-type ACP intermediates can afford more stable aromatization heterocyclic products. In 2020, Shi and coworkers reported a Cu-catalyzed 1,4-difunctionalization reaction of 1,3-enyne-ACPs with Togni I reagent and TMSCN to afford 3-trifluoroethylcyclopenta[b]naphthalene-4-carbonitrile derivatives 42 in moderate to good yields (Scheme 41) [77]. The proposed mechanism indicated that the CF₃ radical generated from Togni I reagent added to the 1,3-enyne-ACPs to form allenyl radicals M-91 after tautomerization. Allenyl radicals M-91 are captured by the LCu^II-CN complex followed by the reductive elimination to produce allene-ACP products M-92. The 6π-electrocyclizaton of M-92 gives vinylcyclopropane intermediates M-93 which undergoes CN-catalyzed cyclopropane ring opening and S_N2 cyclization to give cyclopenta[b]naphthalene products 42. In addition, the interaction of vinylcyclopropane intermediate M-93 with cyano anions, followed by the further S_N2 reaction also can give the final product 42.

Other than the popular conjugated 1,3-dienes and 1,3-enynes presented above, special aromatic substrates can also be developed for 1,4-functionalization reactions. Yan et al., in 2018, introduced a Cu-catalyzed reaction to 1,4-difunctionalize the isoquinolinium salts with ethers and halogen anions. The reaction of isoquinolinium salts and esters in the presence of Cu(acac)₂ and TBHP afforded substituted azaarenes 43 in moderate to good yields [78]. However, the dioxane and diethyl ether were found to be less reactive (Scheme 42). The reaction mechanism suggests that the THF radical, generated from the oxidation of THF and tert-butyl hydroperoxide (TBHP) through a Cu-catalyzed process, adds to the C-1 position of 2-benzylisoquinolin-2-ium bromide to form the radial cation M-94 followed by radical resonance to form M-95 which then undergoes a Cu-catalyzed bromine radical coupling and deprotonates to give product 43.

Fullerene is another aromatic substrate which has been used for 1,4-difunctionalization reaction. Jin et al., in 2015, reported a reaction of C₆₀ with benzyl bromides under the Ni-catalysis to afford 1,4-dibenzyl fullerene compounds 44 in good yields (Scheme 43) [79]. Using a cosolvent for the NiCl₂dppe catalysis is essential for the success of this reaction. As shown in the proposed mechanism, Ni⁰L species generated from the reduction of Ni^IIL with Mn reacts with benzyl bromide to form benzyl radicals which add to C₆₀ to afford the fullerene radical M-96 followed by the subsequent coupling with another benzyl radical species to give 1,4-dibenzyl fullerenes 44.

As shown in Figure 2, pent-1-yne derivatives are also good substrates for radical 1,4-difunctionalizations through a critical 1,5-HAT process. Zhu et al., in 2020, introduced a photoredox reaction of heteroalkynes using oxyfluoroalkylation as radical source and using DMSO or H₂O as nucleophiles to afford oxyfluoroalkylated (Z)-alkenes 45/46 in moderate to good yields (Scheme 44) [80]. The CF₃ radical generated from the Umemoto’s reagent adds to the β-carbon of heteroalkynes to form the vinyl radical M-97 which then undergoes 1,5-HAT to give alkyl radicals M-98. Oxidation of M-98 to alkyl cations M-99 followed by nucleophilic attack with DMSO or H₂O leads to the formation of (Z)-alkenol 45c and 46a, respectively.

In 2020, Zhu et al., reported an Ag-mediated fluoro-fluoroalkylation reaction of alkynes [81]. The reaction of alkynes with fluoroalkyltrimethylsilanes (TMSRf) and Selectfluor in the presence of AgNO₃, PhI(OCOCF₃)₂ (PIFA) and CsF afforded γ-fluorinated fluoroalkyated (Z)-alkenes 47 in good yields. However, the reaction of thioalkyne was ineffective (Scheme 45). A proposed reaction pathway indicates that the CF₂CO₂Et radical derived from TMSCF₂CO₂Et adds to an internal alkyne to form the vinyl radical M-100 and then 1,5-HAT to form M-101 followed by Ag-assisted fluorination with Selectfluor reagent to give the product 47a. This reaction can also be conducted under photoredox conditions.

In 2020, Zhu et al., reported an azobisisobutyronitrile (AIBN)-induced trifluoromethyl-alkynylation reaction of thioalkynes to make trifluoromethylated (Z)-enynes 48 in moderate to high yields with excellent regio- and stereoselectivity (Scheme 46) [82]. Moreover, the base treatment of (Z)-enyne 48a provided trifluoromethyl allene 49. The desilylation of 48b with TBAF followed by a Cu-catalyzed click reaction afforded the trifluoromethyl triazole product 50. A reaction mechanism indicates that the CF₃ radical, generated from the reaction of PhC≡CSO₂CF₃ and AIBN, adds to the β-carbon of thioalkyne to form a vinyl radial followed by 1,5-HAT to produce the alkyl radical M-102 which then adds to the electrophilic carbon triple bonds of PhC≡CSO₂CF₃ to yield a new vinyl radical M-103 followed by the β-elimination to give product 48a.

In 2014, Taniguchi et al., reported a unique 1,4-dihydroxylation of terminal and internal alkenes for the synthesis of 1,4-diols 51/52 via 1,5-HAT of oxygen radicals (Scheme 47) [83]. A proposed mechanism indicates that the interaction of Fe phthalocyanine complex with NaBH₄ and O₂ gives a putative Fe^III hydride complex which adds to alkenes to afford intermediates M-104. The reaction of M-104 with O₂ produces tertiary-carbon-centered radicals which are captured by the Fe-complex to afford the iron peroxide complex M-105. The formation of alkoxy radical via the cleavage of the O–O bond of M-105 and 1,5-HAT of the O-radicals give alkyl radicals M-106 which lead to the formation of 1,4-diols 51 after reduction of the radicals and capture of the second O₂.

4. 1,5-Difunctionalization Reactions

All the radical 1,5-difunctionalization reactions summarized in this paper have been published within the last four years and the numbers are limited. These reactions require special substrates that contain vinyl cyclopropane or 5-membered rings with two heteroatoms. The ring-opening to relocate the radicals is the key reaction process which allows the second functionalization at the 5-position (Figure 3). A representative pathway for the reaction of vinyl cyclopropanes is shown in Scheme 48. In the reaction process, the addition of initial X radical generates cyclopropylmethyl radicals which readily open to form new radicals for the second functionalization with Y to give the products.

An enantioselective 1,5-cyanotrifluoromethylation of vinylcyclopropanes (VCPs) through a Cu-catalyzed radical reaction was reported by Wang et al., in 2019 [84]. The reaction of VCPs, Togni’s reagent I and TMSCN in the presence of Cu(acac)₂ and chiral oxazoline ligand afforded CF₃-containing alkenylnitriles 53 in good yields and ee ratio (Scheme 49). The reaction mechanism shows that CF₃ radical derived from the Togni I reagent adds to the C=C bond of vinylcyclopropane to form alkyl radical M-107 and then benzylic radical M-108 after β-fragmentation of the cyclopropane ring. The enantioselective reaction of M-108 with chiral LCu^II(CN)₂ affords product 53a after reductive elimination of the catalyst.

The Cahard group, in 2021, reported a vinylcyclopropane (VCP)-based 1,5-chloropentafluorosulfanylation for the synthesis of allylic pentafluorosulfanyl derivatives. The reaction of VCPs and SF₅Cl in alkanes in the presence of Et₃B and O₂ gave products 54 in high yields (Scheme 50) [85]. The reaction mechanism suggests that SF₅ radical, generated from the reaction of SF₅Cl with Et₃B and O₂, adds to the C=C bond of VCPs followed by cyclopropane ring-opening and coupling with chlorine radical of SF₅Cl to provide 1,5-chloropentafluorosulfanylation product 54a.

The Yan group, in 2019, reported a benzothiazolim-bromide-based difunctionalization reaction. The Cu-catalyzed reaction of benzothiazolim bromides with benzodioxole afforded 2,5-difunctionalized benzothiazolims 55 in moderate to good yields (Scheme 51) [86]. This reaction initiates with the addition of benzodioxole radical to benzothiazolims at the 2-position followed by resonance relocation of the radical from N atom to 6-position and then oxidative coupling with [Cu]-Br to give products 55.

The Feng group, in 2022, reported the use of 3-alkyl-4-isoxazolines as substrates for a photoredox 1,5-difunctionalization reaction to make α-sulfonyl-β-amino ketone and α-polyfluoroalkyl-β-amino ketone compounds 56 in good to excellent yields (Scheme 52) [87]. The reaction was applied for the preparation of enantiopure α-polyfluoroalkyl-β-amino ketone 57 as well as Fe-catalyzed trifluoromethylation-azidation reaction for making product 58. A reaction mechanism suggests that PhSO₂ radical adds to the 4-position of 4-isoxazoline for radical-addition-induced β-fragmentation (RAIF) to cleave the N–O bond followed by 1,5-HAT and trifluoromethylthiolation to give product 56a.

5. 1,6- and 1,7-Difunctionalization Reactions

Radical 1,6- and 1,7-difunctionalization reactions require special alkene substrates which can undergo 1,5- or 1,6-HAT reactions (Figure 4). Since a couple of recent reviews covered the progress on this topic [88,89], only selective examples and most recent examples are presented herein.

As presented in this paper above (Scheme 44, Scheme 45 and Scheme 46), 1,5-HAT is also involved in the 1,4-difunctionalization reactions. In the case of 1,4-difunctionalization, the initial radical addition happens at the alkyne carbon to form R¹Z-stabilized vinyl radicals which undergo 1,5-HAT to shift the radical to carbon-4 of the initial addition (Scheme 53). Meanwhile in the 1,6-difunctionalization, the initial addition happens at the terminal carbon of alkenes to give alkyl radicals which undergo 1,5-HAT to shift the radical to carbon-6 of the initial addition.

In 2014, the Liu group reported an asymmetric 1,6-alkoxytrifluoromethylation reaction of alkenes under the Cu and chiral phosphoric acid (CPA) co-catalysis [90]. The reaction of alkenes, Togni’s reagent I and alcohols gave the chiral CF₃-containing N,O-aminals 59 in good yields with excellent enantioselectivities (Scheme 54). A reaction mechanism suggests that the CF₃ radical derived from the Togni’s reagent I adds to the terminal carbon of alkenes. The resulting radical M-109 undergoes 1,5-HAT followed by oxidation to give imine compound M-110. The CPA-catalyzed nucleophilic attack of MeOH on imine M-110 affords the chiral product 59a. It is worth noting that when indoles were used as the nucleophiles instead of alcohols under the Cu-CPA catalytic system, a series of chiral trifluoromethylated indole derivatives could be obtained [91]. Similar Cu-catalyzed reactions for racemic products [92] and metal catalyst-free 1,6-difunctionalization of alkenes [93] were also developed by the same group.

Liu and colleagues, in 2015, reported a Cu-catalyzed 1,6-difunctionalization reaction of alkenes to introduce azido and CF₃ groups [94]. The reaction of alkenyl ketones, TMSN₃ and Togni’s reagent II in the presence of CuI afforded 1,6-azidotrifluoromethylation products 60 in good to excellent yields. The CF₃ radical derived from Togni II adds to the terminal carbon of alkene followed by 1,5-HAT to give radical M-111 which is then oxidized by Cu^II to provide cation intermediate M-112. Nucleophilic reaction of M-112 with TMSN₃ affords product 60a (Scheme 55).

In 2015, the Liu and Tan group reported a 1,2-bis(diphenylphosphino)benzene (dppBz)-promoted reaction of alkenes with Togni’s reagent II to give 1,7-bistrifluoromethylated enamides 61 in excellent yields with good regio-, chemo-, and stereoselectivities (Scheme 56) [95]. In the reaction process, the CF₃ radical derived from the Togni’s reagent II adds to alkenes followed by 1,5-HAT to afford a more stabilized α-amido radicals M-113. After single-electron oxidation of M-113 with Togni’s reagent II and deprotonation afford enamides M-114 which react with second CF₃ radical followed by single-electron oxidation to radical cations and deprotonation to furnish 1,7-bistrifluoromethylated enamides 61.

In 2018, Nevado and colleagues described a redox neutral remote 1,6-difunctionalization of alkenes under visible-light irradiation to efficiently create C(sp³)-O and C(sp³)-C(sp²) bonds at the benzylic position in the presence of O- and C-nucleophiles, respectively (Scheme 57) [96]. The reaction of alkenes with alkyl radical precursors and O-/C-based nucleophiles under mild photoredox catalysis gave 1,6-difunctionalized products 62/63 in fair to good yields. A proposed mechanism suggests that varieties of C-centered radicals generated from 2-bromo-2,2-difluoro(or 2-monofluoro)acetates, amides, and alkyl and aryl 2-bromoacetates under redox neutral conditions, reacting with the alkenes to afford vicinal radical intermediates M-115. The 1,5-HAT of M-115 produces a distant benzylic radical M-116 followed by SET oxidation and nucleophilic trapping with O-/C-based nucleophiles to furnish the desired products.

In 2020, the Wang group reported a 1,6-azidotrifluoromethylation reaction of alkenes. The Fe-catalyzed reaction of alkenes, Togni’s reagent II and TMSN₃ gave difunctionalized products 64 in moderate to excellent yields (Scheme 58) [97]. A reaction mechanism suggests that the CF₃ radical derived from the Togni II reagent adds to the terminal carbon of alkenes. The resulting radicals M-117 undergo 1,5-HAT to form M-118 which then react with Fe-N₃ complex to give products 64a–b. This reaction could be extended for 1,7-bifunctionalized via the 1,6-HAT to afford the corresponding products 64c–e.

A method for visible-light-induced 1,6-oxyfluoroalkylation of alkenes was introduced by the Ma group in 2019 [98]. It has a unique reaction sequence of addition of Rf radical to alkene followed by 1,5-HAT and Kornblum oxidation with DMSO to give products 65 (Scheme 59).

In 2021, Chen and colleagues reported a photoredox 1,6-difunctionalization reaction of azaaryl-attached alkenes. The reaction of azaaryl alkenes and RfSO₂Na in the presence of photosensitizer dicyanopyrazine (DPZ) afforded 1,6-deuteroalkylation products 66 in good yields (Scheme 60) [99]. Some commercially available fluoroalkanesulfinic acid sodium salts can smoothly undergo single-electron oxidation to generate fluoroalkyl radicals mediated by visible light. Then, the radical addition of unactivated terminal olefins with the fluoroalkyl radical generates the carbon radical M-119, and the 1,n-HAT process is carried out to afford the key radical M-120. The relative anion M-121 generated by the reduction of M-120 undergoes deuteration with D₂O to deliver the final 1,6- or 1,7-bifunctionalized product 66.

Yu and colleagues, in 2020, introduced a photoredox reaction for the difunctionalization of alkenes with CO₂ and CF₃ groups. The CF₃ radical generated from CF₃SO₂Na adds to the alkenes followed by 1,5-HAT to afford radicals M-122 which are then reduced by Ir^II to anions M-123. Nucleophilic reaction of M-123 with CO₂ gives product 67 after protonation (Scheme 61) [100]. Other than CO₂, electrophiles such as aryl aldehydes, aromatic ketoesters and benzyl bromides can be used for making diverse difunctionalized products. In 2022, the Yu group reported photoredox 1,6- and 1,7-dicarboxylation reactions of alkenes with CO₂. A variety of unactivated aliphatic alkenes can undergo double carboxylations to afford dicarboxylic acids 68 in moderate to good yields (Scheme 62) [101].

In 2016, the Zhu group presented a new method for the synthesis of ε-CF₃-substituted amides involving the 1,5-HAT to form acyl radicals as the key step [102]. The Cu-catalyzed reaction of alkenals, Togni’s reagent II and amines in the presence of CuSO₄ and K₂CO₃ afforded products 69 in good yields (Scheme 63). In the reaction process, CF₃ radical derived from Togni II adds to the terminal carbon of alkenes followed by 1,5-HAT, trapping the acyl radicals M-124 with amines, oxidation via SET afford products 69 after deprotonation.

The Zhu group, in 2017, reported another 1,6-difunctionalization reaction involving the remote-HAT process to form acyl radicals. The Pd-catalyzed reaction of alkenyl aldehydes, arylboronic acids and fluoroalkyl bromides afforded difluoroalkylated ketones 70 in good to excellent yields (Scheme 64) [103]. A reaction mechanism suggests that the fluoroalkyl radicals generated from fluoroalkyl halides add to the alkene moiety of alkenyl aldehydes, followed by 1,5-HAT to form the acyl radicals M-125, transmetallation with Pd^I species and then with ArB(OH)₂ to afford aryldifluoroalkylation products 70 after reductive elimination of the Pd-cat. The Zhu group also reported a similar reaction of alkenyl aldehydes, arylboronic acids and tertiary α-carbonyl alkyl bromides under Ni-catalysis to afford quaternary carbon-containing ketones 71 (Scheme 65) [104].

In 2017, the Gagosz group reported a Cu-catalyzed remote oxidative difunctionalization reaction of alkenols. The reaction of alkenols and Togni’s reagent II in the presence of Cu(OAc)₂ and bipyridine afforded various trifluoromethylated ketones 72 in good yields (Scheme 66) [105]. In the reaction process, the CF₃ radical derived from the Togni II reagent adds to alkenes followed by 1,5- or 1,6-HAT to afford more stable α-hydroxy radicals M-126 which are then oxidized by Cu^II to provide 1,6- or 1,7-bifunctionalized product 72. The Liu and Luo groups also reported these types of reactions [106,107]. In 2018, Liu and colleagues disclosed a reaction of alkenols to introduce sulfonyl, phosphony-, and malonate groups to the products 73–75 (Scheme 67) [108].

The radical-induced 1,2-migration of boronate complexes has been recently developed for making functionalized organoboronic acid esters [109,110]. In 2021, the Studer group reported a photo reaction of alkenyl boronate complexes with a cascade sequence of perfluoroalkyl radical addition, 1,5- or 1,6-HAT, SET oxidation, and 1,2-alkyl/aryl migration for the construction of remotely 1,5- and 1,6-difunctionalized organoboronic esters (Scheme 68) [111]. The alkenyl boronate can be produced in situ by the reaction of the related alkenyl boronic esters with alkyl/aryl lithium reagents. By changing the alkyl/aryl lithium donors and perfluoroalkyl radical precursors, a wide variety of highly functionalized organoboronic esters 76 and 77 can be produced.

Recently, Xia and colleagues reported a 1,6-iminosulfonylation reaction by reacting alkenes with oxime esters to afford diverse imine sulfones 78 in moderate yields (Scheme 69) [112]. In the reaction process, an iminyl radical and a sulfonyl radical are generated from the benzophenone oxime ester via homolysis of the N−O bond under photocatalytic conditions. The sulfonyl radical adds to the alkenes followed by 1,5-HAT to afford key radicals M-127. The coupling of M-127 and the iminyl radical gives products 78.

6. Conclusions

Remote radical difunctionalization presents a new research field that is currently the subject of much interest. Most papers summarized in this article have been published within the last five years. Among the different kinds of remote difunctionalization reactions, 1,4- and 1,6-difunctionalizations have been well established due to the development of suitable substrates such as 1,3-dienes/1,3-enynes and 6-subsitituted alk-1-enes. For future work to extend the scope of difunctionalization reactions, design and development of new substrates that bear the scaffolds suitable for expected radical rearrangements via resonance, hydrogen atom/group transfer, and strained ring opening are the key factors for success. The recent developments in photoredox reactions, electrochemical reactions, and transition metal-catalyzed coupling reactions provide new avenues for conducting the initial radical reactions as well as the second functionalization reactions. Many newly developed reagents, such as Togni’s, could be utilized to incorporate CF₃ and other groups into products with medicinal chemistry and drug development applications. We have no doubt that synthetically efficient, operationally simple, and functional-group-diversified remote radical difunctionalization reactions will enjoy more fruitful years to come. We hope that the chemistry highlighted in this paper can be helpful for those who wish to better understand the current status and want to make contributions to the field.

Footnotes

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Figure 1. Substrates for 1,3-difunctionalization with the pointed position for the initial radical reaction.

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Figure 2. Substrates for 1,4-difunctionalization with the pointed position for the initial radical reaction.

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Figure 3. Substrates for 1,5-difunctionalization with the pointed position for the initial reaction.

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Figure 4. Substrates for 1,6- and 1,7-difunctionalization with the pointed position for the initial reaction.

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Scheme 1. Common radical difunctionalization reactions: (I) 1,2-difunctionalization; (II) Radical addition and cyclization for difunctionalization; (III) 1,3-/1,4-/1,5-/1,6-/1,7-difunctionalization.

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Scheme 2. General pathways for 1,3-difunctionalization of allyl or cyclopropyl compounds.

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Scheme 3. 1,3-Difunctionalization of allylboronic esters.

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Scheme 4. 1,3-Difunctionalization of β-alkyl nitroalkenes.

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Scheme 5. Electrochemical 1,3-difunctionalization of arylcyclopropanes.

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Scheme 6. 1,3-Difunctionalization of alkynyl diazo compounds.

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Scheme 7. Visible-light-induced difunctionalization of piperidines.

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Scheme 8. Light-induced 1,3-difunctionalization of alkyl N-hydroxyphthalimide esters.

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Scheme 9. Photoredox and Ni dual-catalyzed reaction of cyclic oxalates.

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Scheme 10. General pathways for the reaction of 1,3-dienes, 1,3-enynes and pent-1-ynes.

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Scheme 11. 1,4-Difunctionalization of 1,3-dienes for N-heterocycle-possessing (E)-olefines.

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Scheme 12. Synthesis of 1,4-difunctionalized (E)-olefines.

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Scheme 13. Synthesis of difluoroalkylated (E)-olefines.

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Scheme 14. Synthesis difluorofunctionalized (E)-alkenes.

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Scheme 15. Ni-Catalyzed reaction of 1,3-enynes.

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Scheme 16. Ni-Catalyzed 1,4-carbofluoroalkylation of 1,3-enynes.

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Scheme 17. Cu-Catalyzed 1,4-sulfonyliodination of 1,3-enynes.

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Scheme 18. Cu-catalyzed 1,4-sulfonylcyanation of 1,3-enynes.

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Scheme 19. 1,4-Sulfonyliodination of 1,3-enynes under metal-free conditions.

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Scheme 20. Ni-catalyzed 1,4-arylsulfonation of 1,3-enynes.

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Scheme 21. Ligand-controlled regioselectivity 1,2- vs. 1,4-addition of 1,3-enynes.

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Scheme 22. Cu-Catalyzed 1,4-bistrifluoromethylation of 1,3-enynes.

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Scheme 23. Cu-catalyzed 1,4-halotrifluoromethylation of 1,3-enynes.

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Scheme 24. 1,4-Trifluoromethylbenzoxylation of 1,3-enynes.

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Scheme 25. Cu-catalyzed 1,4-carbocycanation/trifluoromethylation of 1,3-enynes.

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Scheme 26. Cu-Catalyzed 1,4-selenosulfonylation of 1,3-enynes.

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Scheme 27. Photoredox reaction of vinyl enynes for making 4-sulfonyl allenic alcohols.

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Scheme 28. Reaction of vinyl enynes for making 4-bromoallenic alcohols.

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Scheme 29. Cu and photoredox dual catalysis for 1,4-carbocyanation of 1,3-enynes.

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Scheme 30. Ni/photoredox dual catalysis for 1,4-sulfonylarylation of 1,3-enynes.

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Scheme 31. Ni/photo dual catalysis for 1,4-dicarbonation of 1,3-enynes.

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Scheme 32. NHC-Catalyzed 1,4-alkylcarbonylation of 1,3-enynes.

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Scheme 33. NHC-Catalyzed difluoroolefination of 1,3-enynes.

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Scheme 34. NHC-Catalyzed 1,4-alkylacylation of 1,3-enynes.

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Scheme 35. NHC and photoredox catalysis for 1,4-sulfonylacylation of 1,3-enynes.

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Scheme 36. Cu-catalyzed 1,4-alkylarylation of 1,3-enynes.

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Scheme 37. Cu-Catalyzed alkylcyanation, fluoroalkylcyanation and sulfimidocyanation of 1,3-enynes.

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Scheme 38. Asymmetric 1,4-carbocyanation of 1,3-enynes.

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Scheme 39. Cu-catalyzed asymmetric radical 1,4-carboalkynylation of 1,3-enynes.

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Scheme 40. Synthesis of chiral allenols.

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Scheme 41. Cu-Catalyzed 1,4-difunctionalization of 1,3-enyne-ACPs.

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Scheme 42. 1,4-Difunctionalization of isoquinolinium salts.

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Scheme 43. Ni-catalyzed 1,4-dibenzylation of fullerene.

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Scheme 44. Oxyfluoroalkylation of heteroalkynes.

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Scheme 45. Synthesis of γ-fluorinated fluoroalkyated (Z)-alkenes.

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Scheme 46. Trifluoromethyl-alkynylation of thioalkynes.

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Scheme 47. 1,4-Dihydroxylation of alkenes.

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Scheme 48. Reaction pathway for 1,5-difunctionalization of vinyl cyclopropanes.

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Scheme 49. Asymmetric 1,5-cyanotrifluoromethylation of vinylcyclopropanes.

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Scheme 50. Synthesis of allylic pentafluorosulfanyl derivatives.

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Scheme 51. Difunctionalization of benzothiazolim bromides.

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Scheme 52. Difunctionalization of 4-isoxazolines.

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Scheme 53. 1,n-HAT in 1,4-, 1,6- and 1,7-difunctionalizations.

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Scheme 54. Asymmetric 1,6-oxytrifluoromethylation of alkenes.

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Scheme 55. Synthesis of CF3-containing α-azido ketones.

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Scheme 56. 1,7-Bistrifluoromethylation of alkenes with Togni II reagent.

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Scheme 57. Photoredox 1,6-difunctionalization of alkenes.

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Scheme 58. Fe-catalyzed 1,6- and 1,7-difunctionalization of alkenes.

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Scheme 59. Photocatalytic synthesis of fluoroalkylated ketones.

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Scheme 60. Photoreaction for 1,6- and 1,7-difunctionalization of alkenes.

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Scheme 61. Photoredox 1,7-carboxytrifluoromethylation of alkenes.

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Scheme 62. Photocatalytic 1,7-dicarboxylation of alkenes with CO2.

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Scheme 63. Synthesis of ε-CF3-substituted amides.

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Scheme 64. Pd-Catalyzed aryldifluoroalkylation of alkenyl aldehydes.

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Scheme 65. Ni-Catalyzed remote arylation of alkenyl aldehydes.

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Scheme 66. Cu-catalyzed sequence of hydrotrifluoromethylation/oxidation of alkenols.

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Scheme 67. Hydrofunctionalization with diverse alkenols.

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Scheme 68. Difunctionalizations involving 1,5- or 1,6-HAT and 1,2-migration of boronate complexes.

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Scheme 69. 1,6-Iminosulfonylation of alkenes.

References

1. Chatgilialoglu, C.; Studer, A. Encyclopedia of Radicals in Chemistry, Biology and Materials; Wiley: Chichester, UK, 2012.

2. Zarf, S.Z. Radical Reactions in Organic Synthesis; Oxford University Press: Oxford, UK, 2003.

3. Shen, J.; Li, L.; Xu, J.; Shen, C.; Zhang, P. Recent advances in the application of langlois’ reagent in olefin difunctionalization. Org. Biomol. Chem.; 2023; 21, pp. 2046-2058. [DOI: https://dx.doi.org/10.1039/D2OB01875F] [PubMed: https://www.ncbi.nlm.nih.gov/pubmed/36448510]

4. Dong, B.; Shen, J.; Xie, L. Recent developments on 1,2-difunctionalization and hydrofunctionalization of unactivated alkenes and alkynes involving C–S bond formation. Org. Chem. Front.; 2023; 10, pp. 1322-1345. [DOI: https://dx.doi.org/10.1039/D2QO01699K]

5. Bouchet, D.; Varlet, T.; Masson, G. Strategies toward the difunctionalizations of enamide derivatives for synthesizing α,β-substituted amines. Accounts Chem. Res.; 2022; 55, pp. 3265-3283. [DOI: https://dx.doi.org/10.1021/acs.accounts.2c00540] [PubMed: https://www.ncbi.nlm.nih.gov/pubmed/36318762]

6. Wang, Y.; Bao, Y.; Tang, M.; Ye, Z.; Yuan, Z.; Zhu, G. Recent advances in difunctionalization of alkenes using pyridinium salts as radical precursors. Chem. Commun.; 2022; 58, pp. 3847-3864. [DOI: https://dx.doi.org/10.1039/D2CC00369D]

7. Sarkar, S.; Cheung, K.P.S.; Gevorgyan, V. C–H functionalization reactions enabled by hydrogen atom transfer to carbon-centered radicals. Chem. Sci.; 2020; 11, pp. 12974-12993. [DOI: https://dx.doi.org/10.1039/D0SC04881J]

8. Wu, Y.-C.; Xiao, Y.-T.; Yang, Y.-Z.; Song, R.-J.; Li, J.-H. Recent advances in silver-mediated radical difunctionalization of alkenes. ChemCatChem; 2020; 12, pp. 5312-5329. [DOI: https://dx.doi.org/10.1002/cctc.202000900]

9. Chen, Y.-J.; Qu, Y.-L.; Li, X.; Wang, C.-C. Recent advances in 1,4-functional group migration-mediated radical fluoroalkylation of alkenes and alkynes. Org. Biomol. Chem.; 2020; 18, pp. 8975-8993. [DOI: https://dx.doi.org/10.1039/D0OB01649G]

10. Fu, L.; Greßies, S.; Chen, P.; Liu, G. Recent advances and perspectives in transition metal-catalyzed 1,4-functionalizations of unactivated 1,3-enynes for the synthesis of allenes. Chin. J. Chem.; 2020; 38, pp. 91-100. [DOI: https://dx.doi.org/10.1002/cjoc.201900277]

11. Bao, X.; Li, J.; Jiang, W.; Huo, C. Radical-mediated difunctionalization of styrenes. Synthesis; 2019; 51, pp. 4507-4530. [DOI: https://dx.doi.org/10.1055/s-0039-1690987]

12. Sauer, G.S.; Lin, S. An electrocatalytic approach to the radical difunctionalization of alkenes. ACS Catal.; 2018; 8, pp. 5175-5187. [DOI: https://dx.doi.org/10.1021/acscatal.8b01069]

13. Yao, H.; Hu, W.; Zhang, W. Difunctionalization of alkenes and alkynes via intermolecular radical and nucleophilic additions. Molecules; 2021; 26, 105. [DOI: https://dx.doi.org/10.3390/molecules26010105]

14. Zhi, S.; Yao, H.; Zhang, W. Difunctionalization of dienes, enynes and related compounds via sequential radical addition and cyclization reactions. Molecules; 2023; 28, 1145. [DOI: https://dx.doi.org/10.3390/molecules28031145]

15. Shields, B.J.; Doyle, A.G. Direct C(sp³)–H cross coupling enabled by catalytic generation of chlorine radicals. J. Am. Chem. Soc.; 2016; 138, pp. 12719-12722. [DOI: https://dx.doi.org/10.1021/jacs.6b08397]

16. Cai, Y.; Wang, J.; Zhang, Y.; Li, Z.; Hu, D.; Zheng, N.; Chen, H. Detection of fleeting amine radical cations and elucidation of chain processes in visible-light-mediated [3 + 2] annulation by online mass spectrometric techniques. J. Am. Chem. Soc.; 2017; 139, pp. 12259-12266. [DOI: https://dx.doi.org/10.1021/jacs.7b06319]

17. Park, S.V.; Corcos, A.R.; Jambor, A.N.; Yang, T.; Berry, J.F. Formation of the N≡N triple bond from reductive coupling of a paramagnetic diruthenium nitrido compound. J. Am. Chem. Soc.; 2022; 144, pp. 3259-3268. [DOI: https://dx.doi.org/10.1021/jacs.1c13396]

18. Das, A.; Ahmed, J.; Rajendran, N.M.; Adhikari, D.; Mandal, S.K. A bottleable imidazole-based radical as a single electron transfer reagent. J. Org. Chem.; 2021; 86, pp. 1246-1252. [DOI: https://dx.doi.org/10.1021/acs.joc.0c02465]

19. Luo, S.; Weng, C.; Qin, Z.; Li, K.; Zhao, T.; Ding, Y.; Ling, C.; Ma, Y.; An, J. Tandem H/D exchange-set reductive deuteration strategy for the synthesis of α,β-deuterated amines using D₂O. J. Org. Chem.; 2021; 86, pp. 11862-11870. [DOI: https://dx.doi.org/10.1021/acs.joc.1c01276]

20. Gong, Q.; Cheng, K.; Wu, Q.; Li, W.; Yu, C.; Jiao, L.; Hao, E. One-pot access to ethylene-bridged BODIPY dimers and trimers through single-electron transfer chemistry. J. Org. Chem.; 2021; 86, pp. 15761-15767. [DOI: https://dx.doi.org/10.1021/acs.joc.1c01824]

21. Laha, J.K.; Gupta, P. Sulfoxylate anion radical-induced aryl radical generation and intramolecular arylation for the synthesis of biarylsultams. J. Org. Chem.; 2022; 87, pp. 4204-4214. [DOI: https://dx.doi.org/10.1021/acs.joc.1c03031]

22. Liu, H.; Laporte, A.G.; Tardieu, D.; Hazelard, D.; Compain, P. Formal glycosylation of quinones with exo-glycals enabled by iron-mediated oxidative radical–polar crossover. J. Org. Chem.; 2022; 87, pp. 13178-13194. [DOI: https://dx.doi.org/10.1021/acs.joc.2c01635]

23. Wen, J.; Zhao, W.; Gao, X.; Ren, X.; Dong, C.; Wang, C.; Liu, L.; Li, J. Synthesis of [1,2,3]triazolo-[1,5-a]quinoxalin-4(5H)-ones through photoredox-catalyzed [3 + 2] cyclization reactions with hypervalent iodine(III) reagents. J. Org. Chem.; 2022; 87, pp. 4415-4423. [DOI: https://dx.doi.org/10.1021/acs.joc.2c00135] [PubMed: https://www.ncbi.nlm.nih.gov/pubmed/35234036]

24. Liu, L.; Zhang, Y.; Zhao, W.; Wen, J.; Dong, C.; Hu, C.; Li, J. Photoredox-catalyzed cascade sp² C–H bond functionalization to construct substituted acridine with diarylamine and hypervalent iodine(III) reagents. Org. Lett.; 2023; 25, pp. 592-596. [DOI: https://dx.doi.org/10.1021/acs.orglett.2c04114] [PubMed: https://www.ncbi.nlm.nih.gov/pubmed/36656299]

25. Long, T.; Zhu, C.; Li, L.; Shao, L.; Zhu, S.; Rueping, M.; Chu, L. Ligand-controlled stereodivergent alkenylation of alkynes to access functionalized trans- and cis-1,3-dienes. Nat. Commun.; 2023; 14, 55. [DOI: https://dx.doi.org/10.1038/s41467-022-35688-2] [PubMed: https://www.ncbi.nlm.nih.gov/pubmed/36599820]

26. Rezazadeh, S.; Martin, M.I.; Kim, R.S.; Yap, G.P.A.; Rosenthal, J.; Watson, D.A. Photoredox-nickel dual-catalyzed C-alkylation of secondary nitroalkanes: Access to sterically hindered α-tertiary amines. J. Am. Chem. Soc.; 2023; 145, pp. 4707-4715. [DOI: https://dx.doi.org/10.1021/jacs.2c13174]

27. Xian, N.; Yin, J.; Ji, X.; Deng, G.; Huang, H. Visible-light-mediated photoredox carbon radical formation from aqueous sulfoxonium ylides. Org. Lett.; 2023; 25, pp. 1161-1165. [DOI: https://dx.doi.org/10.1021/acs.orglett.3c00143]

28. Prier, C.K.; Rankic, D.A.; Macmillan, D.W.C. Visible light photoredox catalysis with transition metal complexes: Applications in organic synthesis. Chem. Rev.; 2013; 113, pp. 5322-5363. [DOI: https://dx.doi.org/10.1021/cr300503r]

29. Ji, X.-S.; Zuo, H.-D.; Shen, Y.-T.; Hao, W.-J.; Tu, S.-J.; Jiang, B. Electrochemical selective annulative amino-ketalization and amino-oxygenation of 1,6-enynes. Chem. Commun.; 2022; 58, pp. 10420-10423. [DOI: https://dx.doi.org/10.1039/D2CC03922B]

30. Wan, J.; Huang, J. Electrochemically enabled sulfoximido-oxygenation of alkenes with NH-sulfoximines and alcohols. Org. Lett.; 2022; 24, pp. 8914-8919. [DOI: https://dx.doi.org/10.1021/acs.orglett.2c03774]

31. Xiang, H.; He, J.; Qian, W.; Qiu, M.; Xu, H.; Duan, W.; Ouyang, Y.; Wang, Y.; Zhu, C. Electroreductively induced radicals for organic synthesis. Molecules; 2023; 28, 857. [DOI: https://dx.doi.org/10.3390/molecules28020857]

32. Wang, X.; Li, R.; Deng, Y.; Fu, M.; Zhao, Y.; Guan, Z.; He, Y. Direct hydroxylarylation of benzylic carbons (sp³/sp²/sp) via radical–radical cross-coupling powered by paired electrolysis. J. Org. Chem.; 2023; 88, pp. 329-340. [DOI: https://dx.doi.org/10.1021/acs.joc.2c02363]

33. Tian, Y.; Zheng, L.; Wang, Z.; Li, Z.; Fu, W. Metal-free electrochemical oxidative difluoroethylation/cyclization of olefinic amides to construct difluoroethylated azaheterocycles. J. Org. Chem.; 2023; 88, pp. 1875-1883. [DOI: https://dx.doi.org/10.1021/acs.joc.2c02579]

34. Yao, W.; Lv, K.; Xie, Z.; Qiu, H.; Ma, M. Catalyst-free electrochemical sulfonylation of organoboronic acids. J. Org. Chem.; 2023; 88, pp. 2296-2305. [DOI: https://dx.doi.org/10.1021/acs.joc.2c02690]

35. Yan, M.; Kawamata, Y.; Baran, P.S. Synthetic organic electrochemical methods since 2000: On the verge of a renaissance. Chem. Rev.; 2017; 117, pp. 13230-13319. [DOI: https://dx.doi.org/10.1021/acs.chemrev.7b00397]

36. Jana, K.; Bhunia, A.; Studer, A. Radical 1,3-difunctionalization of allylboronic esters with concomitant 1,2-boron shift. Chem; 2020; 6, pp. 512-522. [DOI: https://dx.doi.org/10.1016/j.chempr.2019.12.022]

37. Wang, Y.; Zheng, L.; Shi, X.; Chen, Y. 1,3-Difunctionalization of β-alkyl nitroalkenes via combination of lewis base catalysis and radical oxidation. Org. Lett.; 2021; 23, pp. 886-889. [DOI: https://dx.doi.org/10.1021/acs.orglett.0c04106]

38. Peng, P.; Yan, X.; Zhang, K.; Liu, Z.; Zeng, L.; Chen, Y.; Zhang, H.; Lei, A. Electrochemical C−C bond cleavage of cyclopropanes towards the synthesis of 1,3-difunctionalized molecules. Nat. Commun.; 2021; 12, 3075. [DOI: https://dx.doi.org/10.1038/s41467-021-23401-8]

39. Li, W.; Zhou, L. Synthesis of tetrasubstituted allenes via visible-light-promoted radical 1,3-difunctionalization of alkynyl diazo compounds. Org. Lett.; 2022; 24, pp. 3976-3981. [DOI: https://dx.doi.org/10.1021/acs.orglett.2c01366]

40. Wang, B.; Zhou, M.; Zhou, Q. Visible-light-induced α,γ-C(sp³)–H difunctionalization of piperidines. Org. Lett.; 2022; 24, pp. 2894-2898. [DOI: https://dx.doi.org/10.1021/acs.orglett.2c00831]

41. Luo, M.; Zhu, S.; Shi, C.; Du, Y.; Yang, C.; Guo, L.; Xia, W. Photoinduced remote C(sp³)–H cyanation and oxidation enabled by a vinyl radical-mediated 1,5-HAT strategy. Org. Lett.; 2022; 24, pp. 6560-6565. [DOI: https://dx.doi.org/10.1021/acs.orglett.2c02523]

42. Li, H.; Guo, L.; Feng, X.; Huo, L.; Zhu, S.; Chu, L. Sequential C–O decarboxylative vinylation/C–H arylation of cyclic oxalates via a nickel-catalyzed multicomponent radical cascade. Chem. Sci.; 2020; 11, pp. 4904-4910. [DOI: https://dx.doi.org/10.1039/D0SC01471K]

43. Gu, C.; Ouyang, X.; Song, R.; Li, J. Indium controlled regioselective 1,4-alkylarylation of 1,3-dienes with α-carbonyl alkyl bromides and N-heterocycles. Chem. Commun.; 2020; 56, pp. 1279-1282. [DOI: https://dx.doi.org/10.1039/C9CC08903A] [PubMed: https://www.ncbi.nlm.nih.gov/pubmed/31904057]

44. Huang, H.; Bellotti, P.; Pflüger, P.M.; Schwarz, J.L.; Heidrich, B.; Glorius, F. Three-component, interrupted radical heck/allylic substitution cascade involving unactivated alkyl bromides. J. Am. Chem. Soc.; 2020; 142, pp. 10173-10183. [DOI: https://dx.doi.org/10.1021/jacs.0c03239] [PubMed: https://www.ncbi.nlm.nih.gov/pubmed/32379432]

45. Ma, S.; Li, F.; Zhang, G.; Shi, L.; Wang, X. Highly regioselective difluoroalkylarylation of butadiene through a nickel-catalyzed tandem radical process. ACS Catal.; 2021; 11, pp. 14848-14853. [DOI: https://dx.doi.org/10.1021/acscatal.1c04237]

46. Liu, Z.; Ye, Z.; Chen, Y.; Zheng, Y.; Xie, Z.; Guan, J.; Xiao, J.; Chen, K.; Xiang, H.; Yang, H. Visible-light-induced, palladium-catalyzed 1,4-difunctionalization of 1,3-dienes with bromodifluoroacetamides. Org. Lett.; 2022; 24, pp. 924-928. [DOI: https://dx.doi.org/10.1021/acs.orglett.1c04293] [PubMed: https://www.ncbi.nlm.nih.gov/pubmed/35040648]

47. Terao, J.; Bando, F.; Kambe, N. Ni-catalyzed regioselective three-component coupling of alkyl halides, arylalkynes, or enynes with R–M (M = MgX′, ZnX′). Chem. Commun.; 2009; 2009, pp. 7336-7338. [DOI: https://dx.doi.org/10.1039/b918548h] [PubMed: https://www.ncbi.nlm.nih.gov/pubmed/20024220]

48. Zhang, K.F.; Bian, K.J.; Li, C.; Sheng, J.; Li, Y.; Wang, X.S. Nickel-catalyzed carbofluoroalkylation of 1,3-enynes to access structurally diverse fluoroalkylated allenes. Angew. Chem. Int. Ed.; 2019; 58, pp. 5069-5074. [DOI: https://dx.doi.org/10.1002/anie.201813184]

49. Song, Y.; Song, S.; Duan, X.; Wu, X.; Jiang, F.; Zhang, Y.; Fan, J.; Huang, X.; Fu, C.; Ma, S. Copper-catalyzed radical approach to allenyl iodides. Chem. Commun.; 2019; 55, pp. 11774-11777. [DOI: https://dx.doi.org/10.1039/C9CC05853B]

50. Lv, Y.; Han, W.; Pu, W.; Xie, J.; Wang, A.; Zhang, M.; Wang, J.; Lai, J. Copper-catalyzed regioselective 1,4-sulfonylcyanation of 1,3-enynes with sulfonyl chlorides and TMSCN. Org. Chem. Front.; 2022; 9, pp. 3775-3780. [DOI: https://dx.doi.org/10.1039/D2QO00486K]

51. Lv, Y.; Lai, J.; Pu, W.; Wang, J.; Han, W.; Wang, A.; Zhang, M.; Wang, X. Metal-free highly regioselective 1,4-sulfonyliodination of 1,3-enynes. J. Org. Chem.; 2023; 88, pp. 2034-2045. [DOI: https://dx.doi.org/10.1021/acs.joc.2c02257]

52. Hu, D.-D.; Gao, Q.; Dai, J.-C.; Cui, R.; Li, Y.-B.; Li, Y.-M.; Zhou, X.-G.; Bian, K.-J.; Wu, B.-B.; Zhang, K.-F. et al. Visible-light-induced, autopromoted nickel-catalyzed three-component arylsulfonation of 1,3-enynes and mechanistic insights. Sci. China Chem.; 2022; 65, pp. 753-761. [DOI: https://dx.doi.org/10.1007/s11426-021-1193-5]

53. Wang, F.; Wang, D.; Zhou, Y.; Liang, L.; Lu, R.; Chen, P.; Lin, Z.; Liu, G. Divergent synthesis of CF₃-substituted allenyl nitriles by ligand-controlled radical 1,2- and 1,4-addition to 1,3-enynes. Angew. Chem. Int. Ed.; 2018; 57, pp. 7140-7145. [DOI: https://dx.doi.org/10.1002/anie.201803668]

54. Shen, H.; Xiao, H.; Zhu, L.; Li, C. Copper-catalyzed radical bis(trifluoromethylation) of alkynes and 1,3-enynes. Synlett; 2020; 31, pp. 41-44. [DOI: https://dx.doi.org/10.1055/s-0039-1690187]

55. Huang, J.; Jia, Y.; Li, X.; Duan, J.; Jiang, Z.; Yang, Z. Halotrifluoromethylation of 1,3-enynes: Access to tetrasubstituted allenes. Org. Lett.; 2021; 23, pp. 2314-2319. [DOI: https://dx.doi.org/10.1021/acs.orglett.1c00449]

56. Li, S.; Yang, W.; Shi, J.; Dan, T.; Han, Y.; Cao, Z.; Yang, M. Synthesis of trifluoromethyl-substituted allenols via catalytic trifluoromethylbenzoxylation of 1,3-enynes. ACS Catal.; 2023; 13, pp. 2142-2148. [DOI: https://dx.doi.org/10.1021/acscatal.2c04978]

57. Song, Y.; Fu, C.; Ma, S. Copper-catalyzed syntheses of multiple functionalizatized allenes via three-component reaction of enynes. ACS Catal.; 2021; 11, pp. 10007-10013. [DOI: https://dx.doi.org/10.1021/acscatal.1c02140]

58. He, F.; Bao, P.; Yu, F.; Zeng, L.; Deng, W.; Wu, J. Copper-catalyzed regioselective 1,4-selenosulfonylation of 1,3-enynes to access cyanoalkylsulfonylated allenes. Org. Lett.; 2021; 23, pp. 7472-7476. [DOI: https://dx.doi.org/10.1021/acs.orglett.1c02665]

59. Zhang, C.; Zhu, J.; Cui, S.; Xie, X.; Wang, X.; Wu, L. Visible-light-induced 1,4-hydroxysulfonylation of vinyl enynes with sulfonyl chlorides: The bridge of chloride linking water and enynes. Org. Lett.; 2021; 23, pp. 3530-3535. [DOI: https://dx.doi.org/10.1021/acs.orglett.1c00943]

60. Xie, X.Y.; Xu, Y.F.; Li, Y.; Wang, X.D.; Zhu, J.; Wu, L. Radical modulated regioselective difunctionalization of vinyl enynes: Tunable access to naphthalen-1(2H)-ones and allenic alcohols. Chem. Commun.; 2022; 58, pp. 3031-3034. [DOI: https://dx.doi.org/10.1039/D1CC06994B]

61. Chen, Y.; Wang, J.; Lu, Y. Decarboxylative 1,4-carbocyanation of 1,3-enynes to access tetra-substituted allenes via copper/photoredox dual catalysis. Chem. Sci.; 2021; 12, pp. 11316-11321. [DOI: https://dx.doi.org/10.1039/D1SC02896K]

62. Chen, Y.; Zhu, K.; Huang, Q.; Lu, Y. Regiodivergent sulfonylarylation of 1,3-enynes via nickel/photoredox dual catalysis. Chem. Sci.; 2021; 12, pp. 13564-13571. [DOI: https://dx.doi.org/10.1039/D1SC04320J]

63. Xu, T.; Wu, S.; Zhang, Q.; Wu, Y.; Hu, M.; Li, J. Dual photoredox/nickel-catalyzed 1,4-sulfonylarylation of 1,3-enynes with sulfinate salts and aryl halides: Entry into tetrasubstituted allenes. Org. Lett.; 2021; 23, pp. 8455-8459. [DOI: https://dx.doi.org/10.1021/acs.orglett.1c03179] [PubMed: https://www.ncbi.nlm.nih.gov/pubmed/34652925]

64. Li, C.; Hu, D.D.; Jin, R.X.; Wu, B.B.; Wang, C.Y.; Ke, Z.F.; Wang, X.S. Selective 1,4-arylsulfonation of 1,3-enynes via photoredox/nickel dual catalysis. Org. Chem. Front.; 2022; 9, pp. 788-794. [DOI: https://dx.doi.org/10.1039/D1QO01653A]

65. Liu, W.; Liu, C.; Wang, M.; Kong, W. Modular synthesis of multifunctionalized CF₃-allenes through selective activation of saturated hydrocarbons. ACS Catal.; 2022; 12, pp. 10207-10221. [DOI: https://dx.doi.org/10.1021/acscatal.2c01521]

66. Chen, L.; Lin, C.; Zhang, S.; Zhang, X.; Zhang, J.; Xing, L.; Guo, Y.; Feng, J.; Gao, J.; Du, D. 1,4-alkylcarbonylation of 1,3-enynes to access tetra-substituted allenyl ketones via an NHC-catalyzed radical relay. ACS Catal.; 2021; 11, pp. 13363-13373. [DOI: https://dx.doi.org/10.1021/acscatal.1c03861]

67. Chen, L.; Wang, J.; Lin, C.; Zhu, Y.; Du, D. CF₂Br₂ as a source for difluoroolefination of 1,3-enynes via N-heterocyclic carbene catalysis. Org. Lett.; 2022; 24, pp. 7047-7051. [DOI: https://dx.doi.org/10.1021/acs.orglett.2c03007]

68. Cai, Y.; Chen, J.; Huang, Y. N-heterocyclic carbene-catalyzed 1,4-alkylacylation of 1,3-enynes. Org. Lett.; 2021; 23, pp. 9251-9255. [DOI: https://dx.doi.org/10.1021/acs.orglett.1c03601]

69. Liu, Y.; Li, Q.; Kou, X.; Zeng, R.; Qi, T.; Zhang, X.; Peng, C.; Han, B.; Li, J. Radical acylalkylation of 1,3-enynes to access allenic ketones via N-heterocyclic carbene organocatalysis. J. Org. Chem.; 2022; 87, pp. 5229-5241. [DOI: https://dx.doi.org/10.1021/acs.joc.2c00037]

70. Wang, L.; Ma, R.; Sun, J.; Zheng, G.; Zhang, Q. NHC and visible light-mediated photoredox Co-catalyzed 1,4-sulfonylacylation of 1,3-enynes for tetrasubstituted allenyl ketones. Chem. Sci.; 2022; 13, pp. 3169-3175. [DOI: https://dx.doi.org/10.1039/D1SC06100C]

71. Ye, C.; Li, Y.; Zhu, X.; Hu, S.; Yuan, D.; Bao, H. Copper-catalyzed 1,4-alkylarylation of 1,3-enynes with masked alkyl electrophiles. Chem. Sci.; 2019; 10, pp. 3632-3636. [DOI: https://dx.doi.org/10.1039/C8SC05689G]

72. Zhu, X.; Deng, W.; Chiou, M.; Ye, C.; Jian, W.; Zeng, Y.; Jiao, Y.; Ge, L.; Li, Y.; Zhang, X. et al. Copper-catalyzed radical 1,4-difunctionalization of 1,3-enynes with alkyl diacyl peroxides and N-fluorobenzenesulfonimide. J. Am. Chem. Soc.; 2019; 141, pp. 548-559. [DOI: https://dx.doi.org/10.1021/jacs.8b11499]

73. Zeng, Y.; Chiou, M.; Zhu, X.; Cao, J.; Lv, D.; Jian, W.; Li, Y.; Zhang, X.; Bao, H. Copper-catalyzed enantioselective radical 1,4-difunctionalization of 1,3-enynes. J. Am. Chem. Soc.; 2020; 142, pp. 18014-18021. [DOI: https://dx.doi.org/10.1021/jacs.0c06177]

74. Dong, X.; Zhan, T.; Jiang, S.; Liu, X.; Ye, L.; Li, Z.; Gu, Q.; Liu, X. Copper-catalyzed asymmetric coupling of allenyl radicals with terminal alkynes to access tetrasubstituted allenes. Angew. Chem. Int. Ed.; 2021; 60, pp. 2160-2164. [DOI: https://dx.doi.org/10.1002/anie.202013022]

75. Zhang, F.; Guo, X.; Zeng, X.; Wang, Z. Asymmetric 1,4-functionalization of 1,3-enynes via dual photoredox and chromium catalysis. Nat. Commun.; 2022; 13, 5036. [DOI: https://dx.doi.org/10.1038/s41467-022-32614-4]

76. Inoue, M.; Nakada, M. Studies into asymmetric catalysis of the nozaki-hiyama allenylation. Angew. Chem. Int. Ed.; 2006; 45, pp. 252-255. [DOI: https://dx.doi.org/10.1002/anie.200502871]

77. Li, P.H.; Wei, Y.; Shi, M. Cu(I)-catalyzed addition-cycloisomerization difunctionalization reaction of 1,3-enyne-alkylidenecyclopropanes (ACPs). Org. Biomol. Chem.; 2020; 18, pp. 7127-7138. [DOI: https://dx.doi.org/10.1039/D0OB01692F]

78. Sun, Q.; Zhang, Y.; Sun, J.; Han, Y.; Jia, X.; Yan, C. Construction of C(sp²)–X (X = Br, Cl) bonds through a copper-catalyzed atom-transfer radical process: Application for the 1,4-difunctionalization of isoquinolinium salts. Org. Lett.; 2018; 20, pp. 987-990. [DOI: https://dx.doi.org/10.1021/acs.orglett.7b03751]

79. Si, W.; Zhang, X.; Asao, N.; Yamamoto, Y.; Jin, T. Ni-catalyzed direct 1,4-difunctionalization of [60]fullerene with benzyl bromides. Chem. Commun.; 2015; 51, pp. 6392-6394. [DOI: https://dx.doi.org/10.1039/C5CC01534K]

80. Shang, T.; Zhang, J.; Zhang, Y.; Zhang, F.; Li, X.; Zhu, G. Photocatalytic remote oxyfluoroalkylation of heteroalkynes: Regio-, stereo-, and site-selective access to complex fluoroalkylated (Z)-alkenes. Org. Lett.; 2020; 22, pp. 3667-3672. [DOI: https://dx.doi.org/10.1021/acs.orglett.0c01163]

81. Shu, C.; Feng, J.; Zheng, H.; Cheng, C.; Yuan, Z.; Zhang, Z.; Xue, X.; Zhu, G. Internal alkyne-directed fluorination of unactivated C(sp³)–H bonds. Org. Lett.; 2020; 22, pp. 9398-9403. [DOI: https://dx.doi.org/10.1021/acs.orglett.0c03730]

82. Xiong, Z.; Zhang, F.; Yu, Y.; Tan, Z.; Zhu, G. AIBN-induced remote trifluoromethyl-alkynylation of thioalkynes. Org. Lett.; 2020; 22, pp. 4088-4092. [DOI: https://dx.doi.org/10.1021/acs.orglett.0c01147]

83. Hashimoto, T.; Hirose, D.; Taniguchi, T. Direct synthesis of 1,4-diols from alkenes by iron-catalyzed aerobic hydration and C–H hydroxylation. Angew. Chem. Int. Ed.; 2014; 53, pp. 2730-2734. [DOI: https://dx.doi.org/10.1002/anie.201308675] [PubMed: https://www.ncbi.nlm.nih.gov/pubmed/24488606]

84. Zhang, Z.; Meng, X.; Sheng, J.; Lan, Q.; Wang, X. Enantioselective copper-catalyzed 1,5-cyanotrifluoromethylation of vinylcyclopropanes. Org. Lett.; 2019; 21, pp. 8256-8260. [DOI: https://dx.doi.org/10.1021/acs.orglett.9b03012] [PubMed: https://www.ncbi.nlm.nih.gov/pubmed/31566382]

85. Feng, F.; Ma, J.; Cahard, D. Radical 1,5-chloropentafluorosulfanylation of unactivated vinylcyclopropanes and transformation into α-SF₅ ketones. J. Org. Chem.; 2021; 86, pp. 13808-13816. [DOI: https://dx.doi.org/10.1021/acs.joc.1c01886] [PubMed: https://www.ncbi.nlm.nih.gov/pubmed/34514785]

86. Fang, H.; Sun, Q.; Ye, R.; Sun, J.; Han, Y.; Yan, C. Copper-catalyzed selective difunctionalization of N-heteroarenes through a halogen atom transfer radical process. N. J. Chem.; 2019; 43, pp. 13832-13836. [DOI: https://dx.doi.org/10.1039/C9NJ03471D]

87. Li, X.; Shui, Y.; Shen, P.; Wang, Y.; Zhang, C.; Feng, C. A novel type of radical-addition-induced β-fragmentation and ensuing remote functionalization. Chem; 2022; 8, pp. 2245-2259. [DOI: https://dx.doi.org/10.1016/j.chempr.2022.05.014]

88. Li, W.; Xu, W.; Xie, J.; Yu, S.; Zhu, C. Distal radical migration strategy: An emerging synthetic means. Chem. Soc. Rev.; 2018; 47, pp. 654-667. [DOI: https://dx.doi.org/10.1039/C7CS00507E]

89. Xi, J.-M.; Liao, W.-W. Radical addition to the C=C bond meets (1,n)-HAT: Recent advances in the remote C(sp³)–H or C(sp²)–H functionalization of alkenes. Org. Chem. Front.; 2022; 9, pp. 4490-4506. [DOI: https://dx.doi.org/10.1039/D2QO00793B]

90. Yu, P.; Lin, J.; Li, L.; Zheng, S.; Xiong, Y.; Zhao, L.; Tan, B.; Liu, X. Enantioselective C–H bond functionalization triggered by radical trifluoromethylation of unactivated alkene. Angew. Chem. Int. Ed.; 2014; 53, pp. 11890-11894. [DOI: https://dx.doi.org/10.1002/anie.201405401]

91. Li, T.; Yu, P.; Du, Y.; Lin, J.; Zhi, Y.; Liu, X. Enantioselective α-C–H functionalization of amides with indoles triggered by radical trifluoromethylation of alkenes: Highly selective formation of C–CF₃ and C–C bonds. J. Fluor. Chem.; 2017; 203, pp. 210-214. [DOI: https://dx.doi.org/10.1016/j.jfluchem.2017.03.008]

92. Li, T.; Yu, P.; Lin, J.; Zhi, Y.; Liu, X. Copper-catalyzed redox-triggered remote C–H functionalization: Highly selective formation of C–CF₃ and C=O bonds. Chin. J. Chem.; 2016; 34, pp. 490-494. [DOI: https://dx.doi.org/10.1002/cjoc.201500891]

93. Huang, L.; Zheng, S.; Tan, B.; Liu, X. Metal-free direct 1,6- and 1,2-difunctionalization triggered by radical trifluoromethylation of alkenes. Org. Lett.; 2015; 17, pp. 1589-1592. [DOI: https://dx.doi.org/10.1021/acs.orglett.5b00479]

94. Huang, L.; Lin, J.; Tan, B.; Liu, X. Alkene trifluoromethylation-initiated remote α-azidation of carbonyl compounds toward trifluoromethyl γ-lactam and spirobenzofuranone-lactam. ACS Catal.; 2015; 5, pp. 2826-2831. [DOI: https://dx.doi.org/10.1021/acscatal.5b00311]

95. Yu, P.; Zheng, S.; Yang, N.; Tan, B.; Liu, X. Phosphine-catalyzed remote β-C–H functionalization of amines triggered by trifluoromethylation of alkenes: One-pot synthesis of bistrifluoromethylated enamides and oxazoles. Angew. Chem. Int. Ed.; 2015; 54, pp. 4041-4045. [DOI: https://dx.doi.org/10.1002/anie.201412310]

96. Shu, W.; Merino, E.; Nevado, C. Visible light mediated, redox neutral remote 1,6-difunctionalizations of alkenes. ACS Catal.; 2018; 8, pp. 6401-6406. [DOI: https://dx.doi.org/10.1021/acscatal.8b00707]

97. Bian, K.; Li, Y.; Zhang, K.; He, Y.; Wu, T.; Wang, C.; Wang, X. Iron-catalyzed remote functionalization of inert C(sp³)–H bonds of alkenes via 1,n-hydrogen-atom-transfer by C-centered radical relay. Chem. Sci.; 2020; 11, pp. 10437-10443. [DOI: https://dx.doi.org/10.1039/D0SC03987J]

98. Li, L.; Luo, H.; Zhao, Z.; Li, Y.; Zhou, Q.; Xu, J.; Li, J.; Ma, Y. Photoredox-catalyzed remote difunctionalizations of alkenes to synthesize fluoroalkyl ketones with dimethyl sulfoxide as the oxidant. Org. Lett.; 2019; 21, pp. 9228-9231. [DOI: https://dx.doi.org/10.1021/acs.orglett.9b03594]

99. Chen, X.; Wei, W.; Li, C.; Zhou, H.; Qiao, B.; Jiang, Z. Photoredox-catalyzed synthesis of remote fluoroalkylated azaarene derivatives and the α-deuterated analogues via 1,n-hydrogen-atom-transfer-involving radical reactions. Org. Lett.; 2021; 23, pp. 8744-8749. [DOI: https://dx.doi.org/10.1021/acs.orglett.1c03204]

100. Song, L.; Fu, D.M.; Chen, L.; Jiang, Y.X.; Ye, J.H.; Zhu, L.; Lan, Y.; Fu, Q.; Yu, D.G. Visible-light photoredox-catalyzed remote difunctionalizing carboxylation of unactivated alkenes with CO₂. Angew. Chem. Int. Ed.; 2020; 59, pp. 21121-21128. [DOI: https://dx.doi.org/10.1002/anie.202008630]

101. Song, L.; Wang, W.; Yue, J.; Jiang, Y.; Wei, M.; Zhang, H.; Yan, S.; Liao, L.; Yu, D. Visible-light photocatalytic di- and hydro-carboxylation of unactivated alkenes with CO₂. Nat. Catal.; 2022; 5, pp. 832-838. [DOI: https://dx.doi.org/10.1038/s41929-022-00841-z]

102. Cheng, C.; Liu, S.; Lu, D.; Zhu, G. Copper-catalyzed trifluoromethylation of alkenes with redox-neutral remote amidation of aldehydes. Org. Lett.; 2016; 18, pp. 2852-2855. [DOI: https://dx.doi.org/10.1021/acs.orglett.6b01113]

103. Nie, X.; Cheng, C.; Zhu, G. Palladium-catalyzed remote aryldifluoroalkylation of alkenyl aldehydes. Angew. Chem. Int. Ed.; 2017; 56, pp. 1898-1902. [DOI: https://dx.doi.org/10.1002/anie.201611697] [PubMed: https://www.ncbi.nlm.nih.gov/pubmed/28079957]

104. Jin, W.; Zhou, Y.; Zhao, Y.; Ma, Q.; Kong, L.; Zhu, G. Nickel-catalyzed remote arylation of alkenyl aldehydes initiated by radical alkylation with tertiary α-carbonyl alkyl bromides. Org. Lett.; 2018; 20, pp. 1435-1438. [DOI: https://dx.doi.org/10.1021/acs.orglett.8b00221] [PubMed: https://www.ncbi.nlm.nih.gov/pubmed/29436837]

105. Lonca, G.H.; Ong, D.Y.; Tran, T.M.H.; Tejo, C.; Chiba, S.; Gagosz, F. Anti-markovnikov hydrofunctionalization of alkenes: Use of a benzyl group as a traceless redox-active hydrogen donor. Angew. Chem. Int. Ed.; 2017; 56, pp. 11440-11444. [DOI: https://dx.doi.org/10.1002/anie.201705368] [PubMed: https://www.ncbi.nlm.nih.gov/pubmed/28722345]

106. Li, L.; Ye, L.; Ni, S.; Li, Z.; Chen, S.; Du, Y.; Li, X.; Dang, L.; Liu, X. Phosphine-catalyzed remote α-C–H bond activation of alcohols or amines triggered by the radical trifluoromethylation of alkenes: Reaction development and mechanistic insights. Org. Chem. Front.; 2017; 4, pp. 2139-2146. [DOI: https://dx.doi.org/10.1039/C7QO00500H]

107. Zhang, J.; Jin, W.; Cheng, C.; Luo, F. Copper-catalyzed remote oxidation of alcohols initiated by radical difluoroalkylation of alkenes: Facile access to difluoroalkylated carbonyl compounds. Org. Biomol. Chem.; 2018; 16, pp. 3876-3880. [DOI: https://dx.doi.org/10.1039/C8OB00889B]

108. Wang, N.; Ye, L.; Li, Z.; Li, L.; Li, Z.; Zhang, H.; Guo, Z.; Gu, Q.; Liu, X. Hydrofunctionalization of alkenols triggered by the addition of diverse radicals to unactivated alkenes and subsequent remote hydrogen atom translocation. Org. Chem. Front.; 2018; 5, pp. 2810-2814. [DOI: https://dx.doi.org/10.1039/C8QO00734A]

109. Leonori, D.; Aggarwal, V.K. Lithiation–borylation methodology and its application in synthesis. Accounts Chem. Res.; 2014; 47, pp. 3174-3183. [DOI: https://dx.doi.org/10.1021/ar5002473]

110. Kischkewitz, M.; Friese, F.W.; Studer, A. Radical-induced 1,2-migrations of boron ate complexes. Adv. Synth. Catal.; 2020; 362, pp. 2077-2087. [DOI: https://dx.doi.org/10.1002/adsc.201901503]

111. Wang, D.; Jana, K.; Studer, A. Intramolecular hydrogen atom transfer induced 1,2-migration of boronate complexes. Org. Lett.; 2021; 23, pp. 5876-5879. [DOI: https://dx.doi.org/10.1021/acs.orglett.1c01998]

112. Luo, X.-L.; Li, S.-S.; Jiang, Y.-S.; Liu, F.; Li, S.-H.; Xia, P.-J. Photocatalytic 1,2-iminosulfonylation and remote 1,6-iminosulfonylation of olefins. Org. Lett.; 2023; 25, pp. 1742-1747. [DOI: https://dx.doi.org/10.1021/acs.orglett.3c00437]