Photoredox Catalysis with Visible Light

Abstract

On the sunny side: Recent examples of visible-light-promoted photoredox catalysis in the presence of [Ru(bpy)3]2+ as an efficient photocatalyst have set new standards for conducting challenging reactions under mild and environmentally benign conditions. The increasing need for more efficient synthetic methods and sustainable processes can be seen as a major driving force for new inventions; it also stimulates the creative rethinking of known concepts, which, in turn, will lead to the development of innovative chemistry.1 For example, starting from the challenge to mimic and understand enzymatic transformations, organocatalysis has now become an important tool in modern organic synthesis with new reactivity that complements that of enzyme and metal catalysis.2 As early as the beginning of the 20th century, photochemistry had already attracted the attention of (organic) chemists.3 But recent years have seen broader interest in photochemical transformations because of the generally mild conditions required for substrate activation—ideally light alone—and their suitability for "green reactions". While classical photochemical steps have found notable applications in synthesis4 and the direct transformation of light into electric energy (photovoltaics) can already be considered a highly developed research field,5 efforts in photocatalysis have mainly targeted the development of artificial photosynthesis systems for the conversion of solar energy into storable chemical fuels.6 However, despite the obvious, practical advantages of visible light as an "infinitely available" promoter for chemical synthesis, the simple inability of most organic molecules to absorb light in the visible range of the spectrum has greatly limited the potential applications of photochemical reactions. One major strategy to address this drawback and to develop new efficient processes using visible light is the use of photosensitizers and photocatalysts.7 Upon irradiation, molecules are converted into their photoexcited states, which are chemically more reactive because of the significantly altered electronic distribution. Apart from following various common physical decay pathways, these photoexcited states can undergo chemical "deactivation" processes, which are either unimolecular and correspond to classical photochemical transformations (isomerizations, rearrangements, etc.) or proceed in a bimolecular manner. The interactions with other species range from bimolecular reactions such as photocycloadditions to quenching processes.8 Here, the most important pathways are energy-transfer reactions9 and electron-transfer reactions; both play a crucial role as indirect initiators for all types of photocatalytic reactions.10 Photoredox catalysis relies on the general property of excited states to be both more easily reduced as well as more easily oxidized than their corresponding ground states, and so the photocatalyst can serve either as an electron donor or an electron acceptor to be regenerated in the catalytic cycle (Scheme 1). The photocatalyst undergoes two distinct electron-transfer steps; both the "quenching" and the "regenerative" electron transfer can be productive with respect to a desired chemical transformation. Ideally, the two electron-transfer processes are connected by the substrates or intermediates of the catalyzed reaction and therefore do not require any sacrificial electron donor or acceptor. Photoredox catalysis by reductive or oxidative pathways. Oxidation steps are depicted in red; reduction steps are in blue. PCat=photocatalyst, Q=quencher, D=donor, A=acceptor. Recent research has focused on the use of the widely applicable and extensively studied organometallic ruthenium(II) polypyridine complexes (e.g. [Ru(bpy)3]2+), which are superior photoredox catalysts not only because of their absorbance in the visible range (λmax≈450 nm), but also because of their unique properties in terms of chemical stability, excited-state lifetimes (originating from metal-to-ligand charge-transfer (MLCT)), and the favorable redox potentials in the excited state that can be fine-tuned by the adjacent ligands.11 As photoredox catalysts, [Ru(bpy)3]2+ complexes serve as visible-light-activated single-electron-transfer (SET) agents; they mediate rapid, low-barrier one-electron steps to induce alternative reaction pathways12 and have set new standards for effecting challenging transformations under mild and environmentally benign conditions.4a, 10 Some initial examples for this highly promising strategy have been published only recently, but they already provide first insights into the versatility of such processes. In photocatalyzed synthesis, so far mainly the reductive properties of photoexcited [Ru(bpy)3]2+* have been used; in other words, following the reduction of excited Ru2+* to a ruthenium(I) species in the presence of sacrificial electron donors such as tertiary amines, the photocatalyst serves as electron donor for different kinds of substrates. A corresponding catalytic cycle is depicted in Scheme 2. Photomediated generation of electron-donating RuI species and subsequent activation of the substrate by reduction. Inspired by the seminal work of Krische et al. on the initiation of the formal [2+2] cycloadditions of bis(enones) by the metal-mediated SET reduction of enones,13 Yoon and co-workers applied Ru-based photoredox catalysis with visible light to generate the required radical anion intermediate from the corresponding aryl enones.14 The electron donor ethyldiisopropylamine was used to generate the reductive Ru+ species.15 Upon irradiation with simple visible-light sources or sunlight, symmetrical and unsymmetrical substrates that possess at least one aryl enone moiety undergo efficient cyclization with high to excellent diastereoselectivity (Scheme 3). Aryl enones with either electron-donating or electron-withdrawing substituents are suitable reaction partners, while a variety of α,β-unsaturated carbonyl compounds can serve as Michael-type acceptors; even quaternary centers can be formed in the case of α-substituted derivatives (R1≠H in Scheme 3). In contrast to the intramolecular reaction, where the cis (meso) isomer is formed preferentially, the intermolecular dimerization affords the all-trans (rac) cyclobutane moieties. Importantly, the authors note that the presence of excess LiBF4 is an additional requirement for the successful reaction. Playing a dual role, the Li salt not only improves the solubility of the reactants in the CH3CN mixture, but possibly also serves as a Lewis acid to facilitate the SET activation of the enone. Visible-light photocatalysis of formal [2+2] cycloadditions of enones. Based on this success for the homodimerization of aryl enone substrates,14 Yoon and co-workers only very recently reported on a highly diastereoselective crossed intermolecular [2+2] cycloaddition of acyclic enones under comparable reaction conditions.16 While higher-energy UV light can be directly absorbed by acyclic enones, it causes predominately photochemical E/Z isomerization of the substrates.17 In contrast, the photocatalyzed reaction proceeds considerably differently. Electron transfer from the Ru sensitizer leads to the formation of the key radical anion intermediate, without intermediate access of the enones′ electronically excited states, and the desired crossed cycloadduct is obtained as a single diastereomer in high yields. For effective heterocoupling, active Michael acceptors are required as suitable electrophilic reaction partners in order to suppress the undesired homodimerization of the aryl enone. Again, electron-rich and electron-poor aryl and heteroaryl enones have proven to be active electrophores, and a variety of α,β-unsaturated carbonyl compounds showed good to excellent acceptor properties as a function of their electrophilic character; thioesters, for example, provided high yields of cross-coupled products (Scheme 4). While the reaction is sensitive to steric bulk at the β position (R1) of the enones and thus requires a greater excess of the acceptor to minimize homocoupling, the use of α-substituted Michael acceptors (R2≠H) allows for the formation of quaternary centers. The potential role of Li+ as a Lewis acidic promoter of the reaction might lead to the development of asymmetric variants of this reaction. Until now, the difference in the redox potentials of aryl-substituted vs. alkyl-substituted and analogous enones has resulted in the high chemoselectivity of this process. An extension of this method to other enone-type substrates as "electrophores" may be possible by fine-tuning the photocatalyst's redox properties through the choice of different ligands. Crossed intermolecular formal [2+2] cycloadditions of acyclic enones. Another example of a highly chemoselective, photoredox-catalyzed reaction with visible light is the tin-free dehalogenation reaction of α-carbonyl and α-aryl halogen derivatives recently disclosed by Stephenson and co-workers (Scheme 5).18 The mild reductive dehalogenation can also be applied to highly functionalized molecules and might therefore prove to be an interesting alternative tool for late-stage removal of halogen atoms in total syntheses. So far, the method tolerates not only silyl ethers and free OH groups, but also esters, amides, carbamates, and alkynes; even in the presence of a vinyl iodide moiety no side reaction, such as the formation of cyclized products, was observed. Tin-free photoredox catalytic reductive dehalogenation. The photomediated reductive cleavage of α-activated carbon–halogen bonds proceeds under mild conditions by a radical mechanism and tolerates a number of different hydrogen sources. When a tenfold excess of iPr2NEt is used, the tertiary amine plays a dual role sacrificially donating an electron to form the Ru reductant and allowing hydrogen-atom transfer from the amine radical cation.19 However, if the amine-based formation of a radical is less

Keywords

Affiliated Institutions

• University of Regensburg DE

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