Photoinduced intermolecular hydrogen atom transfer reactions in organic synthesis

Photocatalytic C-H Functionalization Utilizing Acridine-Lewis Acid Complexes and Pyridine N-oxide Based HAT Catalysts

Pyridine N-oxides have been well established as a class of potent hydrogen-atom-transfer (HAT) catalysts for C-H functionalization of unactivated alkanes and activated C-H substrates. The combination of acridine derivatives and Lewis acids forms in situ-generated photocatalysts that are able to photo-oxidize pyridine N-oxides to generate N-oxide radicals upon irradiation with visible light. Herein, we described a photocatalytic C-H functionalization utilizing acridine-Lewis acid complexes and pyridine N-oxide based HAT catalysts. The readily available and facilely tunable photocatalytic system of acridine-Lewis acid complexes and pyridine N-oxides enables a broad range of substrates with high reactivities (up to 97% yield).

Photoinduced Regio- and Stereoselective Hydrotrifluoromethylation of Glycals with Langlois Reagent

Fluorination has demonstrated the potential to improve the physicochemical and enzymatic properties of carbohydrates. Hydrotrifluoromethylation is an emerging reaction to introduce trifluoromethyl groups. However, the hydrotrifluoromethylation of glycals has been challenging because of the lack of regioselectivity and stereoselectivity. Herein, we describe an efficient, highly selective, and broadly applicable photoinduced hydrotrifluoromethylation strategy of glycals using cost-effective sodium trifluoromethanesulfonate to give 1,2-dideoxy-2-trifluoromethyl sugars.

Photoinduced Copper-Catalyzed Regio- and Diastereoselective Multicomponent [3 + 2 + 1] Radical Cyclization To Access Tetrahydropyridines

The use of simple raw materials to construct complex piperidine scaffolds via multicomponent reactions is highly desirable from the perspectives of atom and step-economy. In this Letter, we present a photoinduced copper-catalyzed three- or four-component [3 + 2 + 1] radical cyclization, utilizing inexpensive and readily available feedstock amines, alkynes, and aldehydes, to synthesize multisubstituted bicyclic or spirocyclic tetrahydropyridines. This method is notable for its mild conditions, atom-economic approach, excellent regio- and diastereoselectivity, and the simultaneous activation of two α-amino C(sp3)-H bonds, resulting in the formation of three C-C bonds and one C-N bond in a single step. Mechanistic studies suggest that the α-aminoalkyl radical is the key intermediate in this reaction, which undergoes sequential radical addition, 1,5-HAT, and 6-exo-trig-type radical cyclization.

Visible-light-driven enantioselective protonation: a new Frontier in asymmetric catalysis

Enantioselective protonation represents a direct and effective method for constructing tertiary carbon stereocenters, which are prevalent in natural products and bioactive compounds. However, achieving catalytic asymmetric protonation has long posed challenges due to difficulties in controlling stereoselectivity. The small size of protons and their rapid transfer rates complicate the selective delivery to active intermediates, resulting in convoluted reaction pathways and pronounced background reactions. In recent years, light-driven photocatalysis has emerged as a powerful strategy in asymmetric protonation reactions, significantly broadening the range of reaction pathways and substrate types. In this review, we highlight recent advancements in this area, focusing on photoinduced single-electron transfer and energy transfer processes, where photosensitizers generate reactive intermediates for asymmetric protonation. This approach not only expands the scope of asymmetric catalysis but also presents new opportunities for green and sustainable chemistry, effectively addressing critical challenges in the construction of complex molecules.

Photochemical Homologated Aminophosphorylation of Carbon-Carbon π-, and σ-Bonds Through Radical Translocation

Difunctionalization of olefins serves as the workhorse for rapid creation of molecular complexity from simple feedstocks. However, these reactions are mostly restricted to the 1,2-variant, with higher homologations being attempted to a much lesser extent. Radical translocation strategies serve as an escape from the traditional 1,2-strategies, providing a means for achieving distant functionalizations that are otherwise difficult to access. Herein, we disclose visible light-mediated strategies for the accessing of 1,3-, 1,4-, 1,5-, and 1,6-aminophosphonates via combination of various radical shifting methods. In addition, the aminophosphorylation of σ-bonds was also achieved, leading to 1,3-aminophosphorylated cyclobutanes.

Photobiocatalytic Enantioselective Benzylic C(sp3)-H Acylation Enabled by Thiamine-Dependent Enzymes via Intermolecular Hydrogen Atom Transfer

Hydrogen atom transfer (HAT) constitutes a powerful mechanism exploited in biology and chemistry to functionalize ubiquitous C(sp3)-H bonds in organic molecules. Despite its synthetic potential, achieving stereocontrol in chemical HAT-mediated C-H functionalization transformations remains challenging. By merging the radical reactivity of thiamine (ThDP)-dependent enzymes with chemical hydrogen atom transfer, we report here a photobiocatalytic strategy for the enantioselective C(sp3)-H acylation of an organic substrate, a transformation not found in nature nor currently attainable by chemical means. This method enables the direct functionalization of benzylic C(sp3)-H sites in a broad range of substrates to furnish valuable enantioenriched ketone motifs with good to high enantioselectivity (up to 96% ee). Mechanistic and spectroscopic studies support the involvement of radical species derived from the Breslow intermediate and C-H substrate, highlight the critical role of the photocatalyst and hydrogen atom abstraction reagents for productive catalysis, and reveal a specific enzyme/photocatalyst interaction favoring single electron transfer during catalysis. Further insights into how the enantioselectivity of the C-C bond-forming reaction is controlled by the enzyme and influenced by active site mutations were gained via molecular modeling. This study illustrates the productive integration of ThDP-mediated biocatalysis with chemical HAT, expanding the range of asymmetric C(sp3)-H functionalization transformations that can be accessed through biocatalysis.

Bridging chemistry and biology for light-driven new-to-nature enantioselective photoenzymatic catalysis

Merging enzymes with light-driven photocatalysis has given rise to the burgeoning field of photoenzymatic catalysis. This approach combines the high reactivity from photoexcitation with the exceptional selectivity of biocatalysis, providing exciting opportunities to tackle challenges in enantioselective radical reactions and to access new-to-nature enzyme reactivities. This tutorial review aims to provide a comprehensive introduction to this interdisciplinary topic, catering to the growing interest from communities in asymmetric catalysis, photocatalysis, radical chemistry, enzyme engineering, and synthetic biology. We summarize the fundamental principles of utilizing light to power enzymatic reactions and different strategies exploring enantioselective photoenzymatic systems, including natural cofactor-based photoenzymatic catalysis, photocatalyst/enzyme synergistic catalysis, synthetic cofactor-based artificial photoenzymes, and cofactor-free photoenzymatic catalysis. We also discuss the challenges and prospects of enantioselective photoenzymatic catalysis in advancing sustainable asymmetric synthesis.

Photocatalytic Stereochemical Editing for the Concise Syntheses of (25S)-Δ7-Dafachronic Acid, Demissidine, and Smilagenin

Stereochemistry editing serves as an important tool to precisely adjust the desired stereochemical configuration of a molecule. In this study, enabled by photocatalytic stereochemical editing of tertiary C─H bonds of steroids, we have completed concise syntheses of (25S)-Δ7-dafachronic acid, demissidine, and smilagenin. The feasibility of regioselectively editing tertiary stereocenters with either very weak α-hydroxyl C─H bonds (in the synthesis of dafachronic acid), α-amino C─H bonds (in the synthesis of demissidine), or with varying steric hindrance (in the synthesis of smilagenin) has been successfully demonstrated.

Copper-Catalyzed Enantioselective Three-Component Carboamidation of Styrenes with Alkanes and Amides

Efficient assembly of valuable chiral molecules from readily available and low-cost chemical feedstocks remains one of the most challenging tasks in synthetic chemistry today. Radical-mediated three-component carboamination of alkenes offers an attractive strategy for addressing this challenge. However, most existing reports focus on racemic examples and are largely limited to activated alkenes, preactivated alkylation reagents, or sufficiently active nucleophiles. Herein, we report a highly enantioselective three-component carboamidation of styrenes with unactivated alkanes and weakly nucleophilic amides. Enantioselective control is achieved by using chiral cationic copper catalysts. This method enables the synthesis of a variety of optically active amides with excellent enantioselectivity. Mechanistic studies reveal that the reaction proceeds via hydrogen atom transfer from the alkane followed by radical addition to the olefin.

Alcohol Activation by Benzodithiolylium for Deoxygenative Alkylation Driven by Photocatalytic Energy Transfer

The 1,3-benzodithiolylium (BDT) cation was identified as an efficient hydroxyl-activating reagent for the photocatalytic deoxygenative radical functionalization of alcohols in the absence of any electron transfer process. A series of unprecedented photocatalytic energy transfer (EnT)-driven deoxygenative radical coupling reactions of alcohols with bifunctional oxime carbonates have been developed based on the activation by BDT. Nickel-catalyzed radical sorting followed by C(sp3)─C(sp3) bond construction facilitates the heteroselective cross-coupling of two distinct alkyl radicals originating from parallel radical relays. These reactions allow the versatile synthesis of diverse nitrogen-containing molecules, including amino acid derivatives, imines, nitriles, and pyrrolines, by using ubiquitous alcohols as regiodefined alkyl building blocks.

Visible-Light-Responsive Tetranuclear Ir-Based Polyoxometalates Achieve Photocatalytic Baeyer-Villiger Oxidation of Ketones

Synthesizing efficient photocatalysts with a broad-spectrum response is crucial for improving solar energy utilization. In this work, we have constructed two examples of tetrameric Ir-based polyoxometalates by introducing an Ir ion. The introduction of Ir ions lowers the band gap energy, and the light absorption range is extended into the visible region. Both displayed satisfactory reactivity for the visible-light-catalyzed Baeyer-Villiger reaction of cyclohexanone, especially compound 1, which reacted up to 95.1% yield for 3 h with TON and TOF values of 951 and 510 h-1, respectively. Meanwhile, 1 also presents excellent cyclic and structural stability, and the yield can still reach 92.2% after five cyclic reactions.

Harnessing Non-Thermal External Stimuli for Polymer Recycling

Polymeric materials have become indispensable due to their versatility and low cost, yet their environmental impact presents a significant global challenge. Traditional chemical recycling methods typically rely on heat as a stimulus; for instance, pyrolysis is a popular chemical recycling methodology which faces limitations due to high energy consumption, low product selectivity, and the generation of undesirable byproducts. In response, recent advances in the promotion of depolymerization and degradation through alternative stimuli such as light, electrochemistry, and mechanical force, have shown promising potential for more efficient and selective polymer breakdown, yielding either the starting monomers or valuable small molecules. This perspective explores key examples of these emerging strategies, highlighting their potential to improve upon current protocols and offer alternative pathways under milder conditions, while identifying significant challenges that future research must address to translate promising chemistry into viable and broadly applicable recycling strategies.

Wavelength-Selective Reactivity of Iron(III) Halide Salts in Photocatalytic C-H Functionalization

The utility of halogen radicals in hydrocarbon functionalization extends from early examples of photochemical halogenation to recent reports using photoredox catalysis with iridium complexes and simple transition metal salts such as FeCl3. The majority of these methods (uncatalyzed and iron-catalyzed) require UV light (λ ≤ 390 nm), and systematic efforts to enable the use of visible light remain valuable. We report the use of a simple Fe(III) salt that enables a C-H to C-C and C-N functionalization under visible light. The reactivity and selectivity profile using different light sources demonstrates wavelength-selective behavior, which was further investigated with deuterium kinetic isotope effect experiments and DFT calculations. These results show that control over the reactive intermediates in this iron-catalyzed reaction can be achieved through proper choice of the wavelength of irradiation.

Photocatalytic Multiple Deuteration of Polyethylene Glycol Derivatives Using Deuterium Oxide

Deuterated molecules are of growing interest because of the specific characteristics of deuterium, such as stronger C-D bonds being stronger than C-H bonds. Polyethylene glycols (PEGs) are widely utilized in scientific fields (e. g., drug discovery and material sciences) as linkers and for the improvement of various properties (solubility in water, stability, etc.) of mother compounds. Therefore, deuterated PEGs can be used as novel tools for drug discovery. Although the H/D exchange reaction (deuteration) is a powerful and straightforward method to produce deuterated compounds, the deuteration of PEGs bearing many unactivated C(sp3)-H bonds has not been developed. Herein, we report the photocatalytic deuteration of multiple sites of PEGs using tetra-n-butylammonium decatungstate (TBADT) and D2O as an inexpensive deuterium source. This deuteration can be adapted to PEG derivatives bearing various substituents ((hetero)aryl, benzoyl, alkyl, etc.). The deuteration efficiencies of the α-oxy C(sp3)-H bonds at the terminal positions of the PEGs were strongly influenced by the substituents. These reactivities were elucidated by density functional theory calculations of the reaction barriers towards the formation of radical intermediates, induced by the excited state of TBADT and the PEG substrate. In addition, the applicability of deuterated PEGs to internal standard experiments and Raman spectroscopy was demonstrated.

Recent Advances in Organic Photocatalyst-Promoted Carbohydrate Synthesis and Modification under Light Irradiation

Photoredox catalysis has been developed as a sustainable and eco-friendly catalytic strategy, which might provide innovative solutions to solve the current synthetic challenges and barriers in carbohydrate chemistry. During the last few decades, the study of organic photocatalyst-promoted carbohydrate synthesis and modification has received significant attention, which provides an excellent and inexpensive metal-free alternative to photoredox catalysis as well as introduces a new fastest-growing era to access complex carbohydrates simply. In this review, we aim to provide an overview of organic photocatalyst-promoted carbohydrate synthesis and modification under light irradiation, which is expected to provide new directions for further investigation.

Photomechanochemistry: harnessing mechanical forces to enhance photochemical reactions

Photomechanochemistry, i.e., the merger of light energy and mechanical forces, is emerging as a new trend in organic synthesis, enabling unique reactivities of fleeting excited states under solvent-minimized conditions. Despite its transformative potential, the field faces significant technological challenges that must be addressed to unlock its full capabilities. In this Perspective, we analyze selected examples to showcase the available technologies to combine light and mechanical forces, including manual grinding, vortex and shaker mixing, rod milling, and ball milling. By examining the advantages and limitations of each approach, we aim to provide an overview of the current state of synthetic photomechanochemistry to identify opportunities for future advancements in this rapidly evolving area of research.

Light-activated hypervalent iodine agents enable diverse aliphatic C-H functionalization

The functionalization of aliphatic C-H bonds is a crucial step in the synthesis and transformation of complex molecules relevant to medicinal, agricultural and materials chemistry. As such, there is substantial interest in the development of general synthetic platforms that enable the efficient diversification of aliphatic C-H bonds. Here we report a hypervalent iodine reagent that releases a potent hydrogen atom abstractor for C-H activation under mild photochemical conditions. Using this reagent, we demonstrate selective (N-phenyltetrazole)thiolation of aliphatic C-H bonds for a broad scope of substrates. The synthetic utility of the thiolated products is showcased through various derivatizations. Simply by altering the radical trapping agent, our method can directly transform C-H bonds into diverse functionalities, including C-S, C-Cl, C-Br, C-I, C-O, C-N, C-C and C=C bonds.

Direct stereoselective C(sp3)-H alkylation of saturated heterocycles using olefins

Despite cross-coupling strategies that enable the functionalization of aromatic heterocycles, the enantioselective C(sp3)-H alkylation of readily available saturated hydrocarbons to construct C(sp3)-C(sp3) bonds remains a formidable challenge. Here we describe a nickel-catalysed enantioselective C(sp3)-H alkylation of saturated heterocycles using olefins, providing an efficient strategy for the stereoselective construction of C(sp3)-C(sp3) bonds. Using readily available and stable olefins and simple saturated nitrogen and oxygen heterocycles as prochiral nucleophiles, the coupling reactions proceed under mild conditions and exhibit broad scope and high functional group tolerance. Furthermore, the enantio- and diastereoselective C(sp3)-H alkylation of saturated hydrocarbons with alkenyl boronates has been achieved, enabling the synthesis of versatile alkyl boronates containing 1,2-adjacent C(sp3) stereocentres. Application of this approach to the late-stage modification of natural products and drugs, as well as to the enantioselective synthesis of a range of chiral building blocks and natural products, is demonstrated.

Wet Photolithography From Hydrogen Abstraction of a Quasi-Orthogonal Aggregation-Induced Emitter

A new aggregation-induced emission (AIE) luminogen is obtained by dimerizing acridin-9(10H)-one (Ac), an aggregation-caused quenching (ACQ) effect monomer via an N─N bond and forming 9H,9'H-[10,10'-biacridine]-9,9'-dione (DiAc) with D2d symmetry. The quenching of DiAc in solution is ascribed to the enhanced basicity promoting hydrogen bonding and then a hydrogen abstraction (HA) reaction and/or an unallowed transition in frontier orbitals with the same symmetry facilitating intersystem crossing. It is found that emissive Ac is one product of the non-emissive DiAc solution in the HA reaction activated by UV irradiation. By exploiting the AIE properties and the HA reaction of DiAc, photolithographic patterning is demonstrated with a paper wetted with DiAc solution.

Constrained Nuclear-Electronic Orbital Transition State Theory Using Energy Surfaces with Nuclear Quantum Effects

Hydrogen-atom transfer is crucial in a myriad of chemical and biological processes, yet the accurate and efficient description of hydrogen-atom transfer reactions and kinetic isotope effects remains challenging due to significant quantum effects on hydrogenic motion, especially tunneling and zero-point energy. In this paper, we combine transition state theory (TST) with the recently developed constrained nuclear-electronic orbital (CNEO) theory to propose a new transition state theory denoted CNEO-TST. We use CNEO-TST with CNEO density functional theory (CNEO-DFT) to predict reaction rate constants for two prototypical gas-phase hydrogen-atom transfer reactions and their deuterated isotopologic reactions. CNEO-TST is similar to conventional TST except that it employs constrained minimized energy surfaces to include zero-point energy and shallow tunneling effects in the effective potential. We find that the new theory predicts reaction rates quite accurately at room temperature. The effective potential surface must be generated by CNEO theory rather than by ordinary electronic structure theory, but because of the favorable computational scaling of CNEO-DFT, the cost is economical even for large systems. Our results show that dynamics calculations with this approach achieve accuracy comparable to variational TST with a semiclassical multidimensional tunneling transmission coefficient at and above room temperature. Therefore, CNEO-TST can be a useful tool for rate prediction, even for reactions involving highly quantal motion, such as many chemical and biochemical reactions involving transfers of hydrogen atoms, protons, or hydride ions.

Homologation of Alkenyl Carbonyls via a Cyclopropanation/Light-Mediated Selective C-C Cleavage Strategy

We report herein our studies on the direct photoactivation of carbonyl cyclopropanes to give biradical intermediates, leading to selective cleavage of the more substituted carbon-carbon bond. Depending on the substrate structure, extended alkenes were isolated or directly reacted in a photo-Nazarov process to give bicyclic products. Based on these results, a unified reductive ring-opening reaction was developed by using diphenyl disulfide as a hydrogen atom transfer (HAT) reagent. By performing a sequential cyclopropanation/selective ring opening reaction, we achieved a CH2 insertion into the α,β bond of both acyclic and cyclic unsaturated carbonyl compounds. Our protocol provides a further tool for the modification of the carbon framework of organic compounds, complementing the recent progress in "skeletal editing".

Visible-Light-Induced C(sp3)-H Activation for Minisci Alkylation of Pyrimidines Using CHCl3 as Radical Source and Oxidant

A highly efficient Minisci reaction of pyrimidines with alkyl radical generated from visible-light-induced activation of simple C(sp3)-H feedstocks such as (cyclo)alkanes, ethers, alcohols, esters, and amides is reported. A mechanistic study revealed that alkyl radical was generated via hydrogen atom transfer (HAT) of C(sp3)-H with dichloromethyl radical (·CHCl2), which was generated by photoreduction of chloroform.

Molecular Photoelectrocatalysis for Radical Reactions

ConspectusMolecular photoelectrocatalysis, which combines the merits of photocatalysis and organic electrosynthesis, including their green attributes and capacity to offer novel reactivity and selectivity, represents an emerging field in organic chemistry that addresses the growing demands for environmental sustainability and synthetic efficiency. This synergistic approach permits access to a wider range of redox potentials, facilitates redox transformations under gentler electrode potentials, and decreases the use of external harsh redox reagents. Despite these potential advantages, this area did not receive significant attention until 2019, when we and others reported the first examples of modern molecular photoelectrocatalysis. These studies showcased the immense synthetic potential of this hybrid strategy, which not only inherits the strengths of its parent fields but also unlocks unprecedented reactivity and selectivity, enabling challenging transformations under mild conditions while minimizing the reliance on external stoichiometric harsh oxidants or reductants.In this Account, we present our efforts to develop photoelectrocatalytic strategies that leverage homogeneous catalysts to facilitate diverse radical reactions. By integrating electrocatalysis with key photoinduced processes such as single electron transfer (SET), ligand-to-metal charge transfer (LMCT), and hydrogen atom transfer (HAT), we have established photoelectrocatalytic methods to transform substrates such as organotrifluoroborates, arenes, carboxylic acids, and alkanes into reactive radical intermediates. These intermediates subsequently engage in heteroarene C-H functionalization reactions. Importantly, under these photoelectrochemical conditions with homogeneous catalysts, reactive radical intermediates generated in the bulk solution readily participate in efficient radical reactions without undergoing further overoxidation into carbocations, a common challenge in conventional electrochemical systems.By further integration of photoelectrocatalysis with asymmetric catalysis, we have developed photoelectrochemical asymmetric catalysis (PEAC), which proves to be efficient in the enantioselective synthesis of chiral nitriles. This approach involves two relay catalytic cycles: the initial photoelectrocatalytic process engenders benzylic radicals from precursors such as alkyl arenes, benzylic carboxylic acids, and aryl alkenes, and these C-radicals are then subjected to enantioselective cyanation in a subsequent copper-electrocatalytic cycle.Within the realm of oxidative photoelectrochemical transformations, the anode serves as a crucial component for recycling or generating the photocatalyst, while the cathode promotes proton reduction. This dual functionality enables oxidative transformations via H2 evolution, eliminating the reliance on external chemical oxidants. Furthermore, the adaptability of electrochemical systems, achieved through precise manipulation of electric current or potential, ensures meticulous control over the generation and turnover of multiple catalytic species of diverse electrochemical properties. This unique tunability allows for exceptional control over the catalytic process. As a result, despite being a relatively nascent field, molecular photoelectrocatalysis has become instrumental in enabling numerous challenging transformations that were once difficult or required harsh conditions.

Photoinduced Pd-Catalyzed 1,4-Dicarbofunctionalization of 1,3-Butadienes via Aliphatic C-H Bond Elaboration

A three-component coupling strategy for 1,4-dicarbofunctionalization of 1,3-butadiene with C-H bearing substrates has been developed using photoinduced Pd catalysis, with aryl bromide serving as the hydrogen atom transfer (HAT) reagent. This photocatalytic coupling process achieves functionalized oxindole motifs in good yield and regioselectivity under mild reaction conditions. The versatility and synthetic utility of this method are demonstrated through the addition of a variety of C-H-bearing partners and various oxindole substrates to both substituted and unsubstituted butadiene.

Construction of a Library of Fatty Acid Esters of Hydroxy Fatty Acids

Fatty Acid Esters of Hydroxy Fatty Acids (FAHFAs) have emerged as extraordinary bioactive lipids, exhibiting diverse bioactivities, from the enhancement of insulin secretion and the optimization of blood glucose absorption to anti-inflammatory effects. The intricate nature of FAHFAs' structure reflects a synthetic challenge that requires the strategic introduction of ester bonds along the hydroxy fatty acid chain. Our research seeks to create an effective methodology for generating varied FAHFA derivatives. Our primary approach centers on a photochemical hydroacylation reaction, merging terminal alkenes, either ω-alkenoic acids or ω-alkenyl alcohols, with commercially available aldehydes. This transformative, environmentally friendly process, orchestrated by phenylglyoxylic acid as the photoinitiator, serves as the linchpin in establishing a practical and relatively simple method for constructing a library of racemic FAHFAs. The ketones produced by the photochemical reactions are easily converted to hydroxy derivatives, which are coupled with caproic, palmitic, or oleic acid, providing a large set of FAHFAs, which broaden our ability for future structure-activity relationship studies.

Photochemical Deracemization of Lactams with Deuteration Enabled by Dual Hydrogen Atom Transfer

Photochemical deracemization has emerged as one of the most straightforward approaches to access highly enantioenriched compounds in recent years. While excited-state events such as energy transfer, single electron transfer, and ligand-to-metal charge transfer have been leveraged to promote stereoablation, approaches relying on hydrogen atom transfer, which circumvent the limitations imposed by the triplet energy and redox potential of racemic substrates, remain underexplored. Conceptually, the most attractive method for tertiary stereocenter deracemization might be hydrogen atom abstraction followed by hydrogen atom donation. However, implementing such a strategy poses significant challenges, primarily because the enantioenriched products are also reactive if the chiral catalyst is unable to differentiate between the two enantiomers. Herein we report a distinct dual hydrogen atom transfer strategy for photochemical deracemization of δ- and γ-lactams, achieving high enantioenrichment and deuterium incorporation despite the inherent reactivity of the products. Mechanistic studies reveal that benzophenone enables nonselective hydrogen atom abstraction while a tetrapeptide-derived thiol dictates the enantioselectivity of the hydrogen atom donation step. More importantly, a pyridine-based alcohol was found to play crucial roles in facilitating the hydrogen atom abstraction as well as enhancing the enantioselectivity of the hydrogen atom donation step.

A modular approach to catalytic stereoselective synthesis of chiral 1,2-diols and 1,3-diols

Optically pure 1,2-diols and 1,3-diols are the most privileged structural motifs, widely present in natural products, pharmaceuticals and chiral auxiliaries or ligands. However, their synthesis relies on the use of toxic or expensive metal catalysts or suffer from low regioselectivity. Catalytic asymmetric synthesis of optically pure 1,n-diols from bulk chemicals in a highly stereoselective and atom-economical manner remains a formidable challenge. Here, we disclose a versatile and modular method for the synthesis of enantioenriched 1,2-diols and 1,3-diols from the high-production-volume chemicals ethane-1,2-diol (MEG) and 1,3-propanediol (PDO), respectively. The key to success is to temporarily mask the diol group as an acetonide, which imparts selectivity to the key step of C(sp3)-H functionalization. Additionally, 1,n-diols containing two stereogenic centers are also prepared through diastereoselective C(sp3)-H functionalization. The late-stage functionalization of biological active compounds and the expedient synthesis of chiral ligands and pharmaceutically relevant molecules further highlight the synthetic potential of this protocol.

Selective Photocatalytic C-H Oxidation of 5-Methylcytosine in DNA

Selective C-H activation on complex biological macromolecules is a key goal in the field of organic chemistry. It requires thermodynamically challenging chemical transformations to be delivered under mild, aqueous conditions. 5-Methylcytosine (5mC) is a fundamentally important epigenetic modification in DNA that has major implications for biology and has emerged as a vital biomarker. Selective functionalisation of 5mC would enable new chemical approaches to tag, detect and map DNA methylation to enhance the study and exploitation of this epigenetic feature. We demonstrate the first example of direct and selective chemical oxidation of 5mC to 5-formylcytosine (5fC) in DNA, employing a photocatalytic system. This transformation was used to selectively tag 5mC. We also provide proof-of-concept for deploying this chemistry for single-base resolution sequencing of 5mC and genetic bases adenine (A), cytosine (C), guanine (G), thymine (T) in DNA on a next-generation sequencing system. This work exemplifies how photocatalysis has the potential to transform the analysis of DNA.

Proton Tunneling Allows a Proton-Coupled Electron Transfer Process in the Cancer Cell

Proton-coupled electron transfer (PCET) is a fundamental redox process and has clear advantages in selectively activating challenging C-H bonds in many biological processes. Intrigued by this activation process, we aimed to develop a facile PCET process in cancer cells by modulating proton tunneling. This approach should lead to the design of an alternative photodynamic therapy (PDT) that depletes the mitochondrial electron transport chain (ETC), the key redox regulator in cancer cells under hypoxia. To observe this depletion process in the cancer cell, we monitored the oxidative-stress-induced depolarization of mitochondrial inner membrane potential (MMP) using fluorescence lifetime imaging microscopy (FLIM). Typically, increasing metabolic stress of cancer cells is reflected in a nontrivial change in the fluorophore's fluorescence lifetime. After 30 min of irradiation, we observed a shift in the mean lifetime value and a drastic drop in overall fluorescence signal. In addition, our PCET strategy resulted in drastic reorganization of mitochondrial morphology from tubular to vesicle-like and causing an overall depletion of intact mitochondria in the hypodermis of C. elegans. These observations confirmed that PCET promoted ROS-induced oxidative stress. Finally, we gained a clear understanding of the proton tunneling effect in the PCET process through photoluminescence experiments and DFT calculations.

Hydroalkylation of unactivated olefins with C(sp3)─H compounds enabled by NiH-catalyzed radical relay

The hydroalkylation reaction of olefins with alkanes is a highly desirable synthetic transformation toward the construction of C(sp3)─C(sp3) bonds. However, such transformation has proven to be challenging for unactivated olefins, particularly when the substrates lack directing groups or acidic C(sp3)─H bonds. Here, we address this challenge by merging NiH-catalyzed radical relay strategy with a HAT (hydrogen atom transfer) process. In this catalytic system, a nucleophilic alkyl radical is generated from a C(sp3)─H compound in the presence of a HAT promotor, which couples with an alkyl metallic intermediate generated from the olefin substrate with a NiH catalyst to form the C(sp3)─C(sp3) bond. Starting from easily available materials, the reaction not only demonstrates wide functional group compatibility but also provides hydroalkylation products with regiodivergence and excellent enantioselectivity through effective catalyst control under mild conditions.

Unlocking the Potential of Deep Eutectic Solvents and Ligand-to-Metal Charge Transfer Processes: A Reusable Iron-and-UV-Based System for Sustainable C-C Bond Formation

Catalytic C-H functionalization has provided new opportunities to access novel organic molecules more sustainably and efficiently. However, these procedures typically rely on precious metals or complex organic catalysts as well as on hazardous solvents or reaction conditions. Herein, a pioneering methodology for direct C-C bond formation enabled by Ligand-to-Metal Charge Transfer (LMCT) and mediated by UV irradiation has been developed using Deep Eutectic Solvents (DESs) as sustainable reaction media. This direct C-H bond functionalization via a radical addition to electrophiles was successfully confirmed over a broad scope of substrates. More importantly, this is the first example of photocatalytic C-C bond formation in DESs. An inexpensive and abundant iron catalyst (FeCl3) was used under air and mild conditions. Different functional groups were well tolerated obtaining promising results that were comparable to those reported in the literature. Additionally, the reaction medium along with the catalyst could be reused for up to 5 consecutive cycles without a significant loss in the reaction outcome. Several green metrics were calculated and compared to those of conventional procedures, revealing the advantages of using DESs.

Catalytic Enantioselective Hydrogen Atom Abstraction Enables the Asymmetric Oxidation of Meso Diols

Desymmetrization of meso diols is an important strategy for the synthesis of chiral oxygen-containing building blocks. Oxidative desymmetrization is an important subclass, but existing methods are often constrained by the need for activated alcohol substrates. We disclose a conceptually distinct strategy toward oxidative diol desymmetrization that is enabled by catalytic enantioselective hydrogen atom abstraction. Following single electron oxidation of a cinchona alkaloid-derived catalyst, enantiodetermining hydrogen atom abstraction generates a desymmetrized ketyl radical intermediate which reacts with either DIAD or O2 before in situ elimination to form valuable hydroxyketone products. A range of cyclic and acyclic meso diols are competent, defining the absolute configuration of up to four stereocenters in a single operation. As well as providing rapid access to complex hydroxyketones, this work emphasizes the broad synthetic potential of harnessing hydrogen atom abstraction in an enantioselective manner.

Decatungstate-Photocatalyzed Hydroamidomethylation of Azobenzenes with N,N-Dimethylamides

A photocatalytic hydroamidomethylation of azobenzenes with N,N-dimethylamides has been developed. Using tetrabutylammonium decatungstate (TBADT) as a photocatalyst, an array of azobenzenes and N,N-dimethylamides reacted smoothly under visible light irradiation, affording previously unreported N-amidomethyl-N,N'-diarylhydrazines in generally high yields. Mechanistic studies indicate that the reaction is enabled by TBADT-mediated hydrogen atom transfer (HAT) photocatalysis. This work is fundamentally different from the previously reported reaction of N,N-dimethylformamide with azobenzenes.

Selective Oxidation of Alcohols to Carbonyls Under Decatungstate-Mediated Photoelectrochemical Conditions

The oxidation of alcohols to the corresponding carbonyl derivatives has been realized under photoelectrochemical conditions in the presence of tetrabutylammonium decatungstate (TBADT) as the homogeneous photocatalyst. The protocol can be applied to both primary and secondary, benzylic and aliphatic alcohols. The desired products are obtained selectively, skipping the need for purposely added chemical oxidants. An in-depth study of photoelectrochemical conditions revealed that the protocol works best under amperostatic conditions in an undivided electrochemical cell irradiated with a 390 nm LED lamp. The comparison with analogous electrochemical and chemical oxidant-promoted photocatalytic transformations demonstrates the superior efficiency and selectivity of the hereby reported photoelectrochemical conditions.

Arylthianthrenium Salts for Triplet Energy Transfer Catalysis

Sigma bond cleavage through electronically excited states allows synthetically useful transformations with two radical species. Direct excitation of simple aryl halides to form both aryl and halogen radicals necessitates UV-C light, so undesired side reactions are often observed and specific equipment is required. Moreover, only aryl halides with extended π systems and comparatively low triplet energy are applicable to synthetically useful energy transfer catalysis. Here we show the conceptual advantages of arylthianthrenium salts (ArTTs) for energy transfer catalysis with high energy efficiency compared to conventional aryl (pseudo)halides and their utility in arylation reactions of ethylene. The fundamental advance is enabled by the low triplet energy of ArTTs that may originate in large part from the electronic interplay between the distinct sulfur atoms in the tricyclic thianthrene scaffold, which is not accessible in either simple (pseudo)halides or other conventional sulfonium salts.

Site-Selective Access to Functionalized Pyrroloquinoxalinones via H-Atom Transfer from N═Csp2-H Bonds of Quinoxalinones

Site-selective hydrogen atom transfer (HAT) from the N═Csp2-H bonds of quinoxaline-2(1H)-ones is a highly attractive but underdeveloped domain. Reported herein is a highly selective, practical, and economically efficient approach for facile assembly of pyrroloquinoxalinones by synergistic photocatalysis and HAT catalysis. The reaction proceeds through bromine radical-mediated HAT of quinoxalinones and imine radical addition to α-cyano-α,β-unsaturated ketones that establishes a cross-coupling/annulation cascade process, resulting in the synthesis of a series of functionalized pyrroloquinoxalinones. This protocol does not require transition metals or excess oxidants and uses easy-to-synthesize starting materials with excellent scalability and broad substrate scope. The establishment of N═Csp2 radical chemistry illustrates great potential for the synthesis of imine-containing molecules that are not possible with some traditional methods.

Photocatalytic Generation of Germyl Radicals from Digermanes Enabling the Hydro/Deuteriogermylation of Alkenes

We have developed a visible-light-induced method to photolyze digermanes through single-electron oxidation using a photocatalyst, in contrast to direct excitation, to generate germyl radicals and achieve the hydro/deuteriogermylation of alkenes. This protocol allows the previously elusive incorporation of the small trimethylgermyl group and deuterium, metabolically stable bioisosteres of tert-butyl and hydrogen, respectively, making this approach attractive in not only organic synthesis but also medicinal chemistry.

Benzyl Alcohol Functionalization of [1.1.1]Propellane with Alkanes and Aldehydes

Bicyclo[1.1.1]pentanes (BCPs) play a crucial role in drug discovery research as C(sp3)-rich bioisosteres of benzene rings. However, the preparation of BCPs with strong alkane C(sp3)-H bonds has not been reported to date. In this study, we reported a method for light-induced benzyl alcohol functionalization of [1.1.1]propellane with aliphatic hydrocarbons (which have not previously been explored for this purpose) and aldehydes under metal- and photocatalyst-free conditions. The BCP products could be transformed into various useful derivatives, demonstrating the utility of the method. Notably, we achieved the synthesis of functionalized BCPs with simple alkanes.

Modular alkene synthesis from carboxylic acids, alcohols and alkanes via integrated photocatalysis

Alkenes serve as versatile building blocks in diverse organic transformations. Despite notable advancements in olefination methods, a general strategy for the direct conversion of carboxylic acids, alcohols and alkanes into alkenes remains a formidable challenge owing to their inherent reactivity disparities. Here we demonstrate an integrated photochemical strategy that facilitates a one-pot conversion of these fundamental building blocks into alkenes through a sequential C(sp3)-C(sp3) bond formation-fragmentation process, utilizing an easily accessible and recyclable phenyl vinyl ketone as the 'olefination reagent'. This practical method not only offers an unparalleled paradigm for accessing value-added alkenes from abundant and inexpensive starting materials but also showcases its versatility through various complex scenarios, including late-stage on-demand olefination of multifunctional molecules, chain homologation of acids and concise syntheses of bioactive molecules. Moreover, initiating from carboxylic acids, alcohols and alkanes, this protocol presents a complementary approach to traditional olefination methods, making it a highly valuable addition to the research toolkit for alkene synthesis.

Photochemical Aerobic Upcycling of Polystyrene Plastics

Although the introduction of plastics has improved humanity's everyday life, the fast accumulation of plastic waste, including microplastics and nanoplastics, have created numerous problems with recent studies highlighting their involvement in various aspects of our lives. Upcycling of plastics, the conversion of plastic waste to high-added value chemicals, is a way to combat plastic waste that is receiving increased attention. Herein, we describe a novel aerobic photochemical process for the upcycling of real-life polystyrene-based plastics into benzoic acid. A new process employing a thioxanthone-derivative, in combination with N-bromosuccinimide, under ambient air and 390 nm irradiation is capable of upcycling real-life polystyrene-derived products in benzoic acid in yields varying from 24-54 %.

Zwitterionic Acridinium Amidate: A Nitrogen-Centered Radical Catalyst for Photoinduced Direct Hydrogen Atom Transfer

The development of small organic molecules that can convert light energy into chemical energy to directly promote molecular transformation is of fundamental importance in chemical science. Herein, we report a zwitterionic acridinium amidate as a catalyst for the direct functionalization of aliphatic C-H bonds. This organic zwitterion absorbs visible light to generate the corresponding amidyl radical in the form of excited-state triplet diradical with prominent reactivity for hydrogen atom transfer to facilitate C-H alkylation with a high turnover number. The experimental and theoretical investigations revealed that the noncovalent interactions between the anionic amidate nitrogen and a pertinent hydrogen-bond donor, such as hexafluoroisopropanol, are crucial for ensuring the efficient generation of catalytically active species, thereby fully eliciting the distinct reactivity of the acridinium amidate as a photoinduced direct hydrogen atom transfer catalyst.

Photoredox/HAT-Catalyzed Intramolecular Hydrocyclization of Alkenes toward 2,3-Fused Quinazolinones and Dihydroquinazolinones

New photochemical approaches to 2,3-fused quinazolinones and dihydroquinazolinones are disclosed. The intramolecular hydrocyclization proceeds in moderate to excellent yields across diverse alkenes with high regioselectivity and diastereocontrol. Mechanistic studies indicated that the radical cascade processes involve thiophenol acting as single-electron transfer and hydrogen atom transfer reagents. The success of the gram-scale synthesis proves the strategy can be used for practical applications.

Synthesis of β-Silyl Amines via Merging Photoinduced Energy and Hydrogen Atom Transfer in Flow

The development of efficient methods for synthesizing β-silyl amines has long been a significant goal in organic synthesis. Previous methods mainly relied on the use of prefunctionalized substrates or special reagents. Herein, we present a visible-light-promoted synthesis approach for β-silyl amines, utilizing a combination of photoinduced energy and hydrogen atom transfer processes. Using flow chemistry technology, a variety of valuable skeletons, including β-silyl amines and α-amino esters, can be produced from readily available feedstocks such as hydrosilanes and simple alkanes. Moreover, the strategy's full-process fluidized production capability highlights its potential for industrial-scale manufacturing. Mechanistic studies revealed that oxime esters can act as radical precursors as well as hydrogen atom transfer reagents.

Direct C(sp3)-H functionalization with aryl and alkyl radicals as intermolecular hydrogen atom transfer (HAT) agents

Recent years have witnessed the emergence of direct intermolecular C(sp3)-H bond functionalization using in situ generated aryl/alkyl radicals as a unique class of hydrogen atom transfer (HAT) agents. A variety of precursors have been exploited to produce these radical HAT agents under photocatalytic, electrochemical or thermal conditions. To date, viable aryl radical precursors have included aryl diazonium salts or aryl azosulfones, diaryliodonium salts, O-benzoyl oximes, aryl sulfonium salts, aryl thioesters, and aryl halides; and applicable alkyl radical sources have included tetrahalogenated methanes (e.g., CCl3Br, CBr4 and CF3I), N-hydroxyphthalimide esters, alkyl bromides, and acetic acid. This review summarizes the current advances in direct intermolecular C(sp3)-H functionalization through key HAT events with in situ generated aryl/alkyl radicals and categorizes the procedures by the specific radical precursors applied. With an emphasis on the reaction conditions, mechanisms and representative substrate scopes of these protocols, this review aims to demonstrate the current trends and future challenges of this emerging field.

A chiral hydrogen atom abstraction catalyst for the enantioselective epimerization of meso-diols

Hydrogen atom abstraction is an important elementary chemical process but is very difficult to carry out enantioselectively. We have developed catalysts, readily derived from the Cinchona alkaloid family of natural products, which can achieve this by virtue of their chiral amine structure. The catalyst, following single-electron oxidation, desymmetrizes meso-diols by selectively abstracting a hydrogen atom from one carbon center, which then regains a hydrogen atom by abstraction from a thiol. This results in an enantioselective epimerization process, forming the chiral diastereomer with high enantiomeric excess. Cyclic and acyclic 1,2-diols are compatible, as are acyclic 1,3-diols. Additionally, we demonstrate the viability of combining our approach with carbon-carbon bond formation in Giese addition. Given the increasing number of synthetic methods involving hydrogen atom transfer steps, we anticipate that this work will have a broad impact in the field of enantioselective radical chemistry.

Radical Polarity

The polarity of a radical intermediate profoundly impacts its reactivity and selectivity. To quantify this influence and predict its effects, the electrophilicity/nucleophilicity of >500 radicals has been calculated. This database of open-shell species entails frequently encountered synthetic intermediates, including radicals centered at sp3, sp2, and sp hybridized carbon atoms or various heteroatoms (O, N, S, P, B, Si, X). Importantly, these computationally determined polarities have been experimentally validated for electronically diverse sets of >50 C-centered radicals, as well as N- and O- centered radicals. High correlations are measured between calculated polarity and quantified reactivity, as well as within parallel sets of competition experiments (across different radical types and reaction classes). These multipronged analyses show a strong relationship between the computed electrophilicity, ω, of a radical and its relative reactivity (krel vs Δω slopes up to 40; showing mere Δω of 0.1 eV affords up to 4-fold rate enhancement). We expect this experimentally validated database will enable reactivity and selectivity prediction (by harnessing polarity-matched rate enhancement) and assist with troubleshooting in synthetic reaction development.

Anomalous Reaction Pathways to Methane Production in Photocatalytic Ethanol Oxidation

Photocatalytic reduction reactions occasionally utilize sacrificial agents to scavenge photogenerated holes, thus enhancing the kinetics and efficiency of electron harvesting. However, exploring alternative hole-mediated oxidation reactions and their potential impact on photoredox processes is limited. This study investigates the products resulting from the oxidation of ethanol, a commonly used hole scavenger, and the underlying mechanisms involved. We examine a homogeneous eosin Y photoreaction scheme containing a Cu complex coordinated with an N-heterocyclic carbene, a combination often employed in CO2 conversion. Under visible-light excitation, this photosystem yields methane as an unusual product, alongside acetaldehyde and carbon monoxide. Mechanistic analysis reveals that ethanol undergoes a catalytic cascade involving oxidative processes, C-C bond cleavage, and intermolecular hydrogen atom transfer. Notably, the Lewis-acidic metal center of the Cu complex activates a novel pathway for ethanol oxidation. This work presents the influence of catalyst selection and reaction condition optimization on the emergence of new or unexpected catalytic processes.

Lewis-Acid-Promoted Visible-Light-Mediated C(sp3)-H Bond Functionalization of Arylvinylpyridines via Diradical Hydrogen Atom Transfer

A visible-light-induced intramolecular diradical-mediated hydrogen atom transfer (DHAT) of primary, secondary, and tertiary C(sp3)-H bonds and subsequent cyclization is described. This transformation is enabled by triplet energy transfer upon Lewis acid coordination to alkyl-substituted arylvinylpyridines and gives access to a variety of benzocyclobutenes (>40 examples, 32-96% yield). Notably, tri- and tetrasubstituted olefins with tertiary C(sp3)-H bonds effectively delivered sterically hindered products with adjacent all-carbon quaternary centers. Mechanistic evidence and density functional theory (DFT) calculations suggest that Lewis acid coordination was crucial for the success by modulating the reactivity of the diradical intermediates to unlock a challenging carbon-to-carbon DHAT and subsequent cyclization with a rather low barrier, which allows the functionalization of benzylic C(sp3)-H bonds to construct otherwise inaccessible benzocyclobutenes.

Chemoselective Approach to Versatile Acyl Fluorides by Photoinduced Activation of p-Methoxybenzyl Esters

A new strategy for the metal-free photoinduced activation of p-methoxybenzyl esters is developed using Selectfluor and benzil for the generation of acyl fluoride intermediates that enable various transformations. The highlight of this activation method is its high chemoselectivity in the presence of other functionalities, such as esters, amides, and ketones. A synthetic application for the preparation of peptide mimetics that possess two different amide units is also described.

Stereoselective and site-divergent synthesis of C-glycosides

Carbohydrates play important roles in medicinal chemistry and biochemistry. However, their synthesis relies on specially designed glycosyl donors, which are often unstable and require multi-step synthesis. Furthermore, the catalytic and stereoselective installation of arylated quaternary stereocentres on sugar rings remains a formidable challenge. Here we report a facile and versatile method for the synthesis of diverse C-R (where R is an aryl, heteroaryl, alkenyl, alkynyl or alkyl) glycosides from readily available and bench-stable 1-deoxyglycosides. The reaction proceeds under mild conditions and exhibits high stereoselectivity across a broad range of glycosyl units. This protocol can be used to synthesize challenging 2-deoxyglycosides, unprotected glycosides, non-classical glycosides and deuterated glycosides. We further developed the catalyst-controlled site-divergent functionalization of carbohydrates for the synthesis of various unexplored carbohydrates containing arylated quaternary stereocentres that are inaccessible by existing methods. The synthetic utility of this strategy is further demonstrated in the synthesis of pharmaceutically relevant molecules and carbohydrates.