Abstract
Intramolecular cyclization of nitrogen-containing molecules onto pendant alkenes is an efficient strategy for the construction of N-heterocycles, which are of paramount importance in, for example, pharmaceuticals and materials. Similar intermolecular cyclization reactions, however, are scarcer for nitrogen building blocks, including N-centred radicals, and divergent and modular versions are not established. Here we report the use of sulfilimines as bifunctional N-radical precursors for cyclization reactions with alkenes to produce N-unprotected heterocycles in a single step through photoredox catalysis. Structurally diverse sulfilimines can be synthesized in a single step, and subsequently engage with alkenes to afford synthetically valuable five-, six- and seven-membered heterocycles. The broad and diverse scope is achievable by a radical-polar crossover annulation enabled by the bifunctional character of the reagents, which distinguishes itself from all other N-centred-radical-based reactions. The modular synthesis of the sulfilimines allows for larger structural diversity of N-heterocycle products than is currently achievable with other single cyclization methods.
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Main
Partially and fully saturated N-heterocycles are of high synthetic value, and can for example be accessed by cyclization onto vinyl sulfonium reagents1,2,3,4, yet their direct synthesis by cyclization reactions to olefins is not generally established. The development of SnAP reagents is an excellent example of how bifunctional reagents5 can quickly generate useful N-heterocycle diversity through cyclization onto aldehydes6, but similar reactivity via a single-step-reaction with alkenes has not been developed. In 2001, Oshima and co-workers reported a radical chain process using N-allyl-N-chlorotosylamide as a nitrogen-radical precursor for reaction with alkenes to generate N-tosylpyrrolidines7. Shi and co-workers developed diaziridinones as nitrogen-centred radical (NCR) precursors for ring expansion with alkenes to generate N-tert-butyl-protected imidazolidinones under copper catalysis8. Xu and co-workers reported the use of functionalized hydroxylamines to generate carbamate-based NCRs for the construction of oxazolidinones under iron catalysis9. Another example uses N-fluorobenzenesulfonimide specifically for the construction of sultams under copper catalysis10. Despite the large synthetic utility, these methods can only generate a single, specific N-heterocycle, typically with an electron-withdrawing nitrogen-protecting group that may be challenging to remove. No single method appears to be available that can generate several different types of N-heterocycles from olefins11. Here we fill this conceptual void and demonstrate a modular approach to access a large variety of different, synthetically valuable heterocycles that are not currently accessible via other NCRs or polar reactions from simple alkenes in a single step (Fig. 1)12. For example, while morpholine syntheses are well known, their one-step synthesis from olefins has not been reported13.
a–c, In this article, bifunctional sulfilimines that feature both nitrogen-radical and polar reactivity have been developed to react with alkenes, giving a divergent and modular approach to versatile N-heterocycles including morpholines, piperazines and oxazepanes (a), dihydrooxazoles (b) and dihydroimidazoles (c). Nu, nucleophilic group; Het, heteroaryl.
NCRs are important intermediates in C–N bond formation reactions14,15,16,17,18,19. Due to the high bond dissociation energy of the N–H bond (107 kcal mol−1 for ammonia)20, NCRs can function as reactive species for intramolecular hydrogen-atom transfer, for example to generate pyrrolidine derivatives21, as in the Hofmann–Löffler–Freytag reaction22,23. NCRs can also function as electrophilic radicals24, adding to electron-rich π systems in alkenes or arenes to form alkyl or aryl amines. Synthetic applications of such reactivity have resulted in successful hydroamination25,26, aminooxygenation27,28,29,30, aminofluorination31,32,33, carboamination34,35 and aminoazidation36,37, all of which introduce two different functional groups to an alkene in a single step. Despite the advance and scope of difunctionalization reactions with NCRs, intermolecular cyclization reactions to furnish N-heterocycles are still challenging because most nitrogen-radical precursors contain sulfonyl or similar groups on the nitrogen to enhance the electrophilicity of the respective NCRs15,24.
Results and discussion
Our goal was to generate a stable reagent that could be transformed into an electrophilic NCR under conditions that would tolerate the presence and reactivity of a pendant nucleophile for subsequent ring closure. While, a priori, several NCR precursors could meet such a goal, one reason why such a compound class has not yet been disclosed may be the synthetic challenge to make these reagents due to undesired cross-reactivity of the pendant nucleophile or undesired reactivity of the nitrogen-activating group. For example, the chloride released upon NCR formation from N-chloroamonium salts may outcompete a pendant hydroxyl group for addition38. Here we report the use of sulfilimines, a substrate class that has previously been used in other transformations39, to address this synthetic challenge. The bifunctional sulfilimine 1 was obtained directly from commercially available reagents in a reaction of aminoethanol and dibenzothiophene-S-oxide activated by triflic anhydride (Fig. 2a). Irradiation of a photoredox catalyst in the presence of sulfilimine 1, acid and styrene results in phenylmorpholine formation (Fig. 2a). Light and photoredox catalyst are essential for the reactivity (Supplementary Tables 1–6). Both Brønsted acids and Lewis acids accelerate cyclization, possibly due to more efficient single electron transfer (SET) from the excited photoredox catalyst to the sulfilimine coordinated to acid (Fig. 2b and Supplementary Table 1). According to the recorded cyclic voltammogram of sulfilimine 1 (Supplementary Fig. 7), no reduction peak was observed within the evaluated potential, which indicates that mesolytic cleavage of the S=N bond in sulfilimine 1 by initial SET to 1 to the corresponding NCR is slow with standard photocatalysts. In contrast, the Bi(OTf)3-coordinated sulfilimine 1 (A) exhibits a high reduction potential (Ep = −0.4 V versus Ag/AgCl, Supplementary Fig. 7), so that fast SET with the excited iridium photocatalyst (E1/2(IrIII*/IrIV) = −1.28 V vs saturated calomel electrode)40 can be observed, to form B (Fig. 2b). Bi(OTf)3 was identified as optimal because Brønsted acids could result in cationic polymerization of activated olefins such as electron-rich styrenes (Supplementary Table 2)41. In addition, both Lewis and Brønsted acids could be responsible for rendering the amine radical electrophilic for polarity-matched addition to the electron-rich π system of the olefin42,43,44. A stoichiometric amount of Bi(OTf)3 is required due to the basicity of the products. A conceptual advantage of the sulfilimines over other NCR precursors is their ability to enable easy introduction of pendant nucleophilic functional groups on NCRs, and directly afford unprotected N–H nitrogen heterocycles in a single step without the need for covalent activating groups or a deprotection step. Upon addition to the π system, the oxidized photoredox catalyst can oxidize the resulting carbon radical C for subsequent intramolecular nucleophilic attack (D) of the pendant nucleophile and regeneration of the photoredox catalyst resting state (Fig. 2b).
a, The sulfilimine 1 was obtained from the reaction of aminoethanol and triflic-anhydride-activated dibenzothiophene-S-oxide in a single step. The reaction optimization shows that both photocatalyst and acid additive are essential for the reactivity; aYield determined from1H NMR with CH2Br2 as an internal standard. bIsolated yield in parenthesis. DCM, dichloromethane; DME, 1,2-dimethoxyethane. b. A radical-polar-crossover annulation process was proposed. The acid additive plays a crucial role in activation of sulfilimine 1 to generate bifunctional NCR B as a key intermediate. DBT, dibenzothiophene. c. X-ray crystal structure of 1 (Supplementary Tables 7 and 8; hydrogen atoms are omitted for clarity). Selected bond distances and angles: S(1)–N(1), 1.591(2) Å; C(1)–S(1)–C(2), 88.85(9)°, C(3)–N(1)–S(1), 116.97(14)°.
Various bifunctional sulfilimine reagents can be synthesized in a single step (Tables 1 and 2). Primary amines including aminoalcohols, diamines and aminopyridines react to produce iminodibenzothiophenes with pendant hydroxyl (3–6), amide (7, 8) or pyridinyl groups (9, 10). The diversity of the suitable sulfilimines for heterocycle synthesis was extended by reaction of the parent iminodibenzothiophene (11) with acylating reagents, which gives access to other classes of sulfilimines, such as those derived from amides, pyrimidines and triazines from acid chlorides (12–15), chloropyrimidines (16) and chlorotriazines (17), respectively. All sulfilimines shown, with the exception of 6, are easily handled solids and are stable in ambient atmosphere without detectable decomposition for at least three months; while also stable, 6 was isolated as an oil.
Cyclization of a variety of sulfilimines with a variety of electron-rich olefins gives access to a large family of diverse, synthetically valuable heterocycles in a single step (Table 3 and Fig. 3). The products can be isolated without protecting groups on nitrogen, but in situ protection of nitrogen with a tert-butyloxycarbonyl (Boc) group is facile, if desired, as shown for 18. Styrene derivatives that are prone to cationic polymerization under acidic conditions45 such as 19 and 22 can selectively react with the bifunctional sulfilimine 1 to produce morpholines in 78% and 55% yield, respectively. Olefins with heteroaryl substituents, such as indoles (24), pyridines (25) and benzothiophenes (28), are well tolerated. The putative bismuth(III)-coordinated amine radicals undergo addition reactions chemoselectively to alkenes in the presence of electron-rich arenes (19), allylic hydrogens (23, 27, 30–33, 35) and even ether (DME) as solvent. Such functional groups are often reactive with other NCRs either via radical addition46,47 or via hydrogen-atom transfer processes48,49,50. In addition to α-styrenes, 1,1-disubstituted alkenes (37) can also undergo cyclization with sulfilimine 1 to produce morpholine heterocycles with a quaternary centre, although for most other investigated alkyl-substituted alkenes that feature allylic hydrogen atoms, allylic amination was observed44. For 1,2-disubstituted alkenes that bear a group that can stabilize a positive charge, high diastereoselectivity is observed for cyclization (26, 27), providing 2,3-disubsituted morpholines. Both trans- and cis-propenylbenzenes produce the same product with the same diastereoselectivity, which supports the proposed intermediacy of NCRs. High regioselectivity is also obtained in reactions with dienes, such as 34 and 35, as cyclization reaction only occurs at the terminal alkene of the diene, producing alkenyl-substituted morpholines. When alkyl-substituted dienes are used, the thermodynamically more stable trans-olefin is obtained as major product (35). In the case of styrene-derived dienes (34), a known photocatalysed isomerization51 occurs to produce cis- and trans-styrenylmorpholines. Cyclic alkenes afford bicyclic and tricyclic morpholines. Highly diastereoselective formation of morpholine derivatives with fused rings is achieved when endocyclic olefins such as norbornene (29), 1-phenyl-1-cyclohexene (30) and indenes (31, 32) are used. Exocyclic olefins such as 7-methyl-4-methylenechromane (33) and camphene (37) are also suitable reaction partners, producing spirocyclic morpholines. These polycyclic heterocycles can be constructed selectively in a single step from the corresponding alkenes, and are not readily accessible via other synthetic methods. Olefins that would afford cations upon radical addition and oxidation that are not sufficiently stabilized, such as in α olefins and 1,2-disubstituted alkenes without stabilizing groups, such as an aryl or vinyl substituent, cannot participate in the reaction (Supplementary Fig. 1), whereas styrene-like, 1,1-disubstituted and diene-based olefins participate successfully. The method can be used for late-stage diversification (38, 39). To further demonstrate the synthetic value of the method, we accomplished a concise synthesis of H1 receptor antagonist 41 (Fig. 3). The modular approach allows us to construct the key morpholine structure directly from alkene 40, which substantially increased the total yield and reduced the step count compared to the previously published procedure52. The reaction requires the use of a stoichiometric amount of dibenzothiophene heterocycle, which, however, can be recycled after successful cyclization; for example, 92% of dibenzothiophene was reisolated after formation of 2.
Reaction conditions: alkene (0.2 mmol), sulfilimine (0.4 mmol), Bi(OTf)3 (0.4 mmol), [Ir(dFppy)3] (2 mol%) in DME (1 ml) at 10 °C under a 30 W blue LED. aMethyl methoxyacetate (1 ml) as solvent instead of DME, and base workup is not applied due to easier purification of these products in ionic form. Other types of N-heterocycles, including oxazepanes, piperazines, dihydrooxazoles, dihydroimidazopyridiniums and dihydroimidazotriazinones, are accessible with the modular cyclization approach. A concise route to H1 receptor antagonist 41 has been developed based on the cyclization method.
The modular approach and the accessibility of various bifunctional sulfilimines enables the synthesis of other types of N-heterocycles under the same reaction conditions by simply changing the substituents on the sulfilimines (Fig. 3). Disubstituted morpholines are obtained when sulfilimines such as 3 or 4 react with alkenes. Although low diastereoselectivity (2:1) was observed when the stereocentre is α to the hydroxy substituent, high diastereoselectivity (>20:1) is obtained when the stereocentre is α to the nitrogen substituent. Other sulfilimine reagents (5–8) enable the construction of oxazepanes (44, 45) and piperazines (46, 47) in synthetically useful yields. We subsequently explored the generality of our modular approach to N-heterocycles with sulfilimines derived from amines other than alkyl amines. Acyl-amine-derived sulfilimines (12–14) can also function as bifunctional reagents, which undergo cyclization with alkenes under the same reaction conditions to produce dihydrooxazoles (50–52)53,54. An intriguing reactivity was discovered when using sulfilimine 15 as substrate, providing tetrahydrobenzofuran 53 exclusively in 89% yield instead of an N-heterocycle. A plausible rationale is that the generated enamine NCR reacts to the more stable carbon-centred radical, which is then involved in annulation with 1,1-diphenylethylene (Supplementary Fig. 13). The photocatalytic annulation strategy can also be applied to heteroaryl-amine-derived sulfilimines (9, 10, 16, 17), generating electrophilic arylamine radicals that are reactive for cyclization with alkenes to form dihydroimidazole derivatives (48, 49, 54, 55). In the case of sulfilimine 17, the initially formed triazinium underwent hydrolysis under basic conditions to form triazinone 55. NCRs with alkyl, aryl and acyl substituents on nitrogen can be accessed via the same photocatalytic method, which is difficult to achieve with other NCR precursors55,56. The scope of heterocycles presented herein exceeds that of other reported single methods12.
Preliminary mechanistic experiments are in agreement with the proposed strategy shown in Fig. 2b (Supplementary Figs. 2–12). A 1:1 mixture of sulfilimine 1 and Bi(OTf)3 results in a new peak potential that is absent in both 1 and Bi(OTf)3 alone, which we assign to the 1–Bi(OTf)3 adduct A as observed in the cyclic voltammogram (Fig. 4a). The high reduction potential (Ep = −0.4 V versus Ag/AgCl) may be responsible for a fast SET from the excited iridium photocatalyst, while reduction of 1 by itself was not observed. The existence of adduct A is further substantiated by ultraviolet–visible spectroscopy through a new absorption maximum at 326 nm (Fig. 4b). Radical clock experiments with 2-vinylcyclopropylbenzene and a 1,6-diene under optimized reaction conditions with sulfilimine 1 produce ring-opened product 56 and cyclization product 57, respectively, in agreement with NCRs (Fig. 4c).
a, Cyclic voltammetry for Bi(OTf)3, sulfilimine 1 and a 1:1 mixture of Bi(OTf)3 and 1 in acetonitrile under a scan rate of 100 mV s–1. A new reduction peak at Ep = −0.4 V versus Ag/AgCl was observed when using a 1:1 mixture of Bi(OTf)3 and 1. b, Ultraviolet–visible spectra of Bi(OTf)3, sulfilimine 1 and a 1:1 mixture of Bi(OTf)3 and 1 in DME (2.5 × 10–5 M). A new absorption peak at 326 nm was observed when using a 1:1 mixture of Bi(OTf)3 and 1. Both cyclic voltammetry and ultraviolet–visible spectra indicate a direct interaction of Bi(OTf)3 with 1, which plays a key role in activation of sulfilimine 1 for the generation of the corresponding NCR. c, A radical clock experiment using both 2-vinylcyclopropylbenzene and 1,6-diene shows that the reactions proceed via generation of NCRs.
Conclusion
Photocatalysed modular synthesis has enabled the construction of various N-heterocycles with different ring types, ring sizes and substituents on the skeleton in a single step by reaction of easily available bifunctional sulfilimines and alkenes. The scope of heterocycles provided here is broader than that of other reported single methods for N-heterocycle synthesis from olefins.
Methods
General procedure for cyclization
Under a nitrogen atmosphere, to a 4 ml borosilicate vial equipped with a magnetic stir bar were added alkene (if solid) (0.200 mmol, 1.00 equiv.), sulfilimine (0.400 mmol, 2.00 equiv.), [Ir(dFppy)3] (3.0 mg, 4.0 µmol, 2.0 mol%), Bi(OTf)3 (262 mg, 0.400 mmol, 2.00 equiv.), DME (1 ml, c = 0.2 M), and alkene (if liquid) (0.200 mmol, 1.00 equiv.). The vial was sealed with a septum cap and irradiated for 6 h at 10 °C using a photoreactor equipped with a blue LED module (KT-Elektronik, ‘100 W Power LED blau 450 nm Aquarium’, 450 nm, 30 W), cooled with two Peltier elements (TEC1-12706). Then, the reaction mixture was concentrated to dryness. The residue was dissolved in DCM (5 ml) and washed with saturated aqueous sodium carbonate solution (5 ml). The aqueous phase was extracted with DCM (2 × 5 ml). The organic phase was dried over Na2SO4 and filtered, and the solvent was removed under reduced pressure. The residue was purified by chromatography on silica gel eluting with CH2Cl2/MeOH (50/1–10/1 v/v) to afford the cyclization product.
Note: The reaction is air sensitive. The Schlenk technique was used to avoid air. For simplicity, in our research, we have opted to execute the transformation for most compounds in a glovebox. Control experiments showed that yields were within the error of measurement if the reaction was carried out using a glovebox or the Schlenk technique.
Data availability
All the data generated or analysed during this study are included in this article and its Supplementary Information. Crystallographic data for the structure reported in this article have been deposited at the Cambridge Crystallographic Data Centre, under deposition numbers 2101016 (1). Copies of the data can be obtained free of charge via https://www.ccdc.cam.ac.uk/structures/.
References
Wang, Y., Zhang, W., Colandrea, V. J. & Jimenez, L. S. Reactivity and rearrangements of dialkyl- and diarylvinylsulfonium salts with indole-2- and pyrrole-2-carboxaldehydes. Tetrahedron 55, 10659–10672 (1999).
Yamanaka, H., Yamane, Y. & Mukaiyama, T. A new method for the preparation of nitrogen-containing heterocycles using diphenylsulfonium triflates. Heterocycles 63, 2813–2826 (2004).
Yar, M., McGarrigle, E. M. & Aggarwal, V. K. An annulation reaction for the synthesis of morpholines, thiomorpholines, and piperazines from β-heteroatom amino compounds and vinyl sulfonium salts. Angew. Chem. Int. Ed. 47, 3784–3786 (2008).
Juliá, F., Yan, J., Paulus, F. & Ritter, T. Vinyl thianthrenium tetrafluoroborate: a practical and versatile vinylating reagent made from ethylene. J. Am. Chem. Soc. 143, 12992–12998 (2021).
Huang, H.-M., Bellotti, P., Ma, J., Dalton, T. & Glorius, F. Bifunctional reagents in organic synthesis. Nat. Rev. Chem. 5, 301–321 (2021).
Vo, C.-V. T., Mikutis, G. & Bode, J. W. SnAP reagents for the transformation of aldehydes into substituted thiomorpholines—an alternative to cross-coupling with saturated heterocycles. Angew. Chem. Int. Ed. 52, 1705–1708 (2013).
Tsuritani, T., Shinokubo, H. & Oshima, K. Radical [3 + 2] annulation of N-allyl-N-chlorotosylamide with alkenes via atom-transfer process. Org. Lett. 3, 2709–2711 (2001).
Yuan, W., Du, H., Zhao, B. & Shi, Y. A mild Cu(I)-catalyzed regioselective diamination of conjugated dienes. Org. Lett. 9, 2589–2591 (2007).
Lu, D.-F., Zhu, C.-L., Jia, Z.-X. & Xu, H. Iron(II)-catalyzed intermolecular amino-oxygenation of olefins through the N–O bond cleavage of functionalized hydroxylamines. J. Am. Chem. Soc. 136, 13186–13189 (2014).
Kaneko, K., Yoshino, T., Matsunaga, S. & Kanai, M. Sultam synthesis via Cu-catalyzed intermolecular carboamination of alkenes with N-fluorobenzenesulfonimide. Org. Lett. 15, 2502–2505 (2013).
Kaur, N. et al. Intermolecular alkene difunctionalizations for the synthesis of saturated heterocycles. Org. Biomol. Chem. 17, 1643–1654 (2019).
Vo, C.-V. T. & Bode, J. W. Synthesis of saturated N-heterocycles. J. Org. Chem. 79, 2809–2815 (2014).
Tzara, A., Xanthopoulos, D. & Kourounakis, A. P. Morpholine as a scaffold in medicinal chemistry: an update on synthetic strategies. ChemMedChem 15, 392–403 (2020).
Zard, S. Z. Recent progress in the generation and use of nitrogen-centred radicals. Chem. Soc. Rev. 37, 1603–1608 (2008).
Xiong, T. & Zhang, Q. New amination strategies based on nitrogen-centered radical chemistry. Chem. Soc. Rev. 45, 3069–3087 (2016).
Chen, J.-R., Hu, X.-Q., Lu, L.-Q. & Xiao, W.-J. Visible light photoredox-controlled reactions of N-radicals and radical ions. Chem. Soc. Rev. 45, 2044–2056 (2016).
Zhao, Y. & Xia, W. Recent advances in radical-based C–N bond formation via photo-/electrochemistry. Chem. Soc. Rev. 47, 2591–2608 (2018).
Wang, P., Zhao, Q., Xiao, W. & Chen, J. Recent advances in visible-light photoredox-catalyzed nitrogen radical cyclization. Green Synth. Catal. 1, 42–51 (2020).
Kwon, K., Simons, R. T., Nandakumar, M. & Roizen, J. L. Strategies to generate nitrogen-centered radicals that may rely on photoredox catalysis: development in reaction methodology and applications in organic synthesis. Chem. Rev. 122, 2353–2428 (2022).
Bordwell, F. G., Harrelson, J. A. Jr. & Lynch, T.-Y. Homolytic bond dissociation energies for the cleavage of α-N–H bonds in carboxamides, sulfonamides, and their derivatives. the question of synergism in nitrogen-centered radicals. J. Org. Chem. 55, 3337–3341 (1990).
Zhang, J. & Pérez-Temprano, M. H. Intramolecular C(sp3)–H bond amination strategies for the synthesis of saturated N-containing heterocycles. Chimia 74, 895–903 (2020).
Hofmann, A. W. Ueber die Einwirkung des Broms in alkalischer Lösung auf die Amine. Ber. Dtsch. Chem. Ges. 16, 558–560 (1883).
Löffler, K. & Freytag, C. Über eine neue Bildungsweise von N-alkylierten Pyrrolidinen. Ber. Dtsch. Chem. Ges. 42, 3427–3431 (1909).
Parsaee, F. et al. Radical philicity and its role in selective organic transformations. Nat. Rev. Chem. 5, 486–499 (2021).
Stella, L. Homolytic cyclizations of N-chloroalkenylamines. Angew. Chem. Int. Ed. 22, 337–350 (1983).
Musacchio, A. J. et al. Catalytic intermolecular hydroaminations of unactivated olefins with secondary alkyl amines. Science 355, 727–730 (2017).
Miyazawa, K., Koike, T. & Akita, M. Regiospecific intermolecular aminohydroxylation of olefins by photoredox catalysis. Chem. Eur. J. 21, 11677–11680 (2015).
Michaelis, D. J., Shaffer, C. J. & Yoon, T. P. Copper(II)-catalyzed aminohydroxylation of olefins. J. Am. Chem. Soc. 129, 1866–1867 (2007).
Williamson, K. S. & Yoon, T. P. Iron-catalyzed aminohydroxylation of olefins. J. Am. Chem. Soc. 132, 4570–4571 (2010).
Patra, T., Das, M., Daniliuc, C. G. & Glorius, F. Metal-free photosensitized oxyimination of unactivated alkenes with bifunctional oxime carbonates. Nat. Catal. 4, 54–61 (2021).
Zhang, H., Song, Y., Zhao, J., Zhang, J. & Zhang, Q. Regioselective radical aminofluorination of styrenes. Angew. Chem. Int. Ed. 53, 11079–11083 (2014).
Lu, D.-F., Zhu, C.-L., Sears, J. D. & Xu, H. Iron(II)-catalyzed intermolecular aminofluorination of unfunctionalized olefins using fluoride ion. J. Am. Chem. Soc. 138, 11360–11367 (2016).
Jiang, H. & Studer, A. Amidyl radicals by oxidation of α-amido-oxy acids: transition-metal-free amidofluorination of unactivated alkenes. Angew. Chem. Int. Ed. 57, 10707–10711 (2018).
Jiang, H. & Studer, A. Intermolecular radical carboamination of alkenes. Chem. Soc. Rev. 49, 1790–1811 (2020).
McAtee, R. C., Noten, E. A. & Stephenson, C. R. J. Arene dearomatization through a catalytic N-centered radical cascade reaction. Nat. Commun. 11, 2528 (2020).
Zhang, B. & Studer, A. Copper-catalyzed intermolecular aminoazidation of alkenes. Org. Lett. 16, 1790–1793 (2014).
Fu, N., Sauer, G. S., Saha, A., Loo, A. & Lin, S. Metal-catalyzed electrochemical diazidation of alkenes. Science 357, 575–579 (2017).
Govaerts, S. et al. Photoinduced olefin diamination with alkylamines. Angew. Chem. Int. Ed. 59, 15021–15028 (2020).
Tian, X., Song, L. & Hashmi, A. S. K. α-Imino gold carbene intermediates from readily accessible sulfilimines: intermolecular access to structural diversity. Chem. Eur. J. 26, 3197–3204 (2020).
Teegardin, K., Day, J. I., Chan, J. & Weaver, J. Advances in photocatalysis: a microreview of visible light mediated ruthenium and iridium catalyzed organic transformations. Org. Process Res. Dev. 20, 1156–1163 (2016).
Throssell, J. J., Sood, S. P., Szwarc, M. & Stannett, V. The instantaneous polymerization of styrene by trifluoroacetic acid. J. Am. Chem. Soc. 78, 1122–1125 (1956).
Ganley, J. M., Murray, P. R. D. & Knowles, R. R. Photocatalytic generation of aminium radical cations for C–N bond formation. ACS Catal. 10, 11712–11738 (2020).
Svejstrup, T. D., Ruffoni, A., Juliá, F., Aubert, V. M. & Leonori, D. Synthesis of arylamines via aminium radicals. Angew. Chem. Int. Ed. 56, 14948–14952 (2017).
Cheng, Q., Chen, J., Lin, S. & Ritter, T. Allylic amination of alkenes with iminothianthrenes to afford alkyl allylamines. J. Am. Chem. Soc. 142, 17287–17293 (2020).
Aoshima, S. & Kanaoka, S. A renaissance in living cationic polymerization. Chem. Rev. 109, 5245–5287 (2009).
Allen, L. J., Cabrera, P. J., Lee, M. & Sanford, M. S. N-Acyloxyphthalimides as nitrogen radical precursors in the visible light photocatalyzed room temperature C–H amination of arenes and heteroarenes. J. Am. Chem. Soc. 136, 5607–5610 (2014).
Ruffoni, A. et al. Practical and regioselective amination of arenes using alkyl amines. Nat. Chem. 11, 426–433 (2019).
Li, J. et al. Site-specific allylic C–H bond functionalization with a copper-bound N-centred radical. Nature 574, 516–521 (2019).
Shaw, M. H., Shurtleff, V. W., Terrett, J. A., Cuthbertson, J. D. & MacMillan, D. W. C. Native functionality in triple catalytic cross-coupling: sp3 C–H bonds as latent nucleophiles. Science 352, 1304–1308 (2016).
Choi, G., Zhu, Q., Miller, D., Gu, C. J. & Knowles, R. R. Catalytic alkylation of remote C–H bonds enabled by proton-coupled electron transfer. Nature 539, 268–271 (2016).
Metternich, J. B. et al. Photocatalytic E → Z isomerization of polarized alkenes inspired bythe visual cycle: mechanistic dichotomy and origin of selectivity. J. Org. Chem. 82, 9955–9977 (2017).
Botta, M., Castiglioni, E., Di Fabio, R., Spinosa, R. & Togninelli, A. Spiro compounds useful as antagonists of the H1 receptor and their asymmetric preparation, pharmaceutical compositions and use in the treatment of sleep disorders. WO patent 2009016085 (2009).
Wu, F., Kaur, N., Alom, N. & Li, W. Chiral hypervalent iodine catalysis enables an unusual regiodivergent intermolecular olefin aminooxygenation. JACS Au 1, 734–741 (2021).
Mumford, E. M., Hemric, B. N. & Denmark, S. E. Catalytic, enantioselective syn-oxyamination of alkenes. J. Am. Chem. Soc. 143, 13408–13417 (2021).
Kärkäs, M. D. Photochemical generation of nitrogen-centered amidyl, hydrazonyl, and imidyl radicals: methodology developments and catalytic applications. ACS Catal. 7, 4999–5022 (2017).
Jiang, H. & Studer, A. Chemistry with N-centered radicals generated by single-electron transfer-oxidation using photoredox catalysis. CCS Chem. 1, 38–49 (2019).
Acknowledgements
We thank N. Haupt, D. Kampen, F. Kohler and D. Margold for mass spectrometry analysis, M. Leutzsch, M. Kochius, S. Tobegen, C. Wirtz and P. Philipps for NMR spectroscopy analysis, J. Rust for X-ray analysis and Y. Wang for the help with Stern–Volmer quenching experiments (all from MPI für Kohlenforschung). We thank B. Lansbergen, E. M. Alvarez, Y. Cai and F. Juliá (all from MPI für Kohlenforschung) for helpful discussions. We thank S. Lin (MPI für Kohlenforschung) for help with revision. We also thank the MPI für Kohlenforschung for funding. Q.C. acknowledges the Alexander von Humboldt Foundation for a Humboldt Research Fellowship.
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Open access funding provided by Max Planck Society.
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Q.C. developed the chemistry and optimized the reaction conditions. Q.C., Z.B. and S.T. explored the substrate scope for cyclization. Q.C. and T.R. wrote the manuscript. T.R. directed the project.
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Nature Chemistry thanks Jia-Rong Chen, A. Stephen K. Hashmi and the other, anonymous, reviewer(s) for their contribution to the peer review of this work.
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Experimental procedures, product characterization, mechanistic studies, Supplementary Figs. 1–13 and Tables 1–8.
Supplementary Data 1
Crystallographic data for compound 1; CCDC reference 2101016
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Cheng, Q., Bai, Z., Tewari, S. et al. Bifunctional sulfilimines enable synthesis of multiple N-heterocycles from alkenes. Nat. Chem. 14, 898–904 (2022). https://doi.org/10.1038/s41557-022-00997-y
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DOI: https://doi.org/10.1038/s41557-022-00997-y
