Atom Transfer Radical Addition Research Articles

Tuning Co-Operative Energy Transfer in Copper(I) Complexes Using Two-Photon Absorbing Diimine-Based Ligand Sensitizers.

Photocatalysis mediated by low energy light wavelengths has potential to enable safer, sustainable synthetic methods. A phenanthroline-derived ligand bathocupSani, with a large two-photon absorption (TPA) cross section was used to construct a heteroleptic complex [Cu(bathocupSani)(DPEPhos)]BF4 and a homoleptic complex [Cu(bathocupSani)2]BF4. The ligand and the respective homoleptic complex with copper exhibit two-photon upconversion with an anti-Stokes shift of 1.2 eV using red light. The complex [Cu(bathocupSani)2]BF4 promoted energy transfer photocatalysis enabling oxidative dimerization of benzylic amines, sulfide oxidation, phosphine oxidation, boronic acid oxidation and atom-transfer radical addition.

Divalent Organocopper Complexes: Masked Radicals for Effective Electrochemically Driven Atom Transfer Radical Addition

Divalent Organocopper Complexes: Masked Radicals for Effective Electrochemically Driven Atom Transfer Radical Addition

Stereodivergent atom transfer radical addition of α-functionalized alkyl iodides to alkynes: a strategy for selective synthesis of both E- and Z-iodoalkenes.

The geometrical control of atom transfer radical addition (ATRA) reactions to alkynes poses significant challenges. Herein, we present a uniform solution by developing a stereodivergent synthetic method for both isomers of the resulting alkene products, starting from the same materials. The synthesis of the thermodynamically more stable isomer utilizes the strategy of uphill catalysis while the accumulation of the less stable isomer is facilitated by a manganese-catalyzed iodo-abstraction/radical rebound process, taking advantage of its reversibility. Various substituted alkyl iodides can be used to provide easy access to both isomers of iodoalkene products with valuable functional groups such as CF3, CF2H, CN, ester, or amide at the allylic position.

Regiodivergent Radical-Relay Alkene Dicarbofunctionalization.

Herein, we report a regiodivergent 1,n-dicarbofunctionalization of unactivated olefins enabled by a Ni-catalyzed radical relay that forges both C(sp3)-C(sp3) and C(sp2)-C(sp3) linkages, even at long-range. Initial studies support an intertwined scenario resulting from the merger of an atom-transfer radical addition (ATRA) and a chain-walking event, with site-selectivity being dictated by a judicious choice of the ligand backbone.

New functionally substitutes cyclopropanecarboxylic acids as ethylene biosynthesis innovative regulators

Background: Derivatives of small carbocycles (cyclobutanes and cyclopropanes) are known as bioactive molecules. Both their natural and synthetic representatives have multiple applications. Particularly, 1-aminocyclopropane-1-carboxylic acid (ACC) serves as the well-studied ethylene biosynthesis precursor. The development of new functionally substituted cyclopropane carboxylic acids, which show promise as effective inhibitors of ethylene biosynthesis, is crucial for regulating the plant cycle and preserving the quality of fruits and vegetables. Objectives: This research focused on the in-silico studies aimed at developing a universal and affordable methodology for synthesizing new analogs of ACC and assessing their modulating activity on ethylene biosynthesis in plants. The findings from this in silico research provide a foundation for the upcoming in vitro studies. Results: The elaborated efficient catalytic system [Cu(I) salt/amine/DMSO] enabled the synthesis of model compounds under mild conditions, resulting in increasing yields up to quantitative levels. For bioactivity preliminary assessment we performed in silico research of newly synthesized (E)-2-phenyl-1-chlorocyclopropane-1-carboxylic acid and drug-design an appropriate 1-amino-derivative as the inhibitor of 1-aminocyclopropane-1-carboxylate oxidase 2 (ACO2) of Arabidopsis thaliana. Docking results showed certain advantages of the newly synthesized compound in comparison to well-known inhibitors of ethylene biosynthesis. Conclusions: The recommended synthetic technology has increased efficiency in yield quantification. In silico studies, a high affinity for ACO2 has been demonstrated. The synthesized compounds exhibit superior characteristics compared to widely used market preparations for regulating ethylene biosynthesis. More detailed comparative in vitro studies are planned. Keywords: plant growth regulation, cyclopropane carboxylic acids, ethylene biosynthesis inhibitors, molecular docking, atom transfer radical addition (ATRA), Cu(I) Complex catalyst.

Investigating Competing Inner‐ and Outer‐Sphere Electron‐Transfer Pathways in Copper Photoredox‐Catalyzed Atom‐Transfer Radical Additions: Closing the Cycle

This integrated computational and experimental study comprehensively examines the viability of competing inner‐sphere electron transfer (ISET) and outer‐sphere electron transfer (OSET) processes in [Cu(dap)2]+‐mediated atom‐transfer radical additions (ATRA) of olefins and CF3SO2Cl that can deliver both R–SO2Cl and R–Cl products. Five sterically‐ and electronically‐varied representative alkenes were selected from which to explore and reconcile the range of experimentally observed outcomes. Findings are consistent with photoexcited [Cu(dap)2]+ initiating photoelectron transfer via ISET and the subsequent regeneration of the oxidized catalyst via single‐electron transfer in the ground state via ISET to close the catalytic cycle and liberate products. R–SO2Cl/R–Cl product ratios appear to be primarily governed by the relative rates of direct catalyst regeneration {i.e., [Cu(dap)2SO2Cl]•+ + R•} and ligand exchange {i.e., [Cu(dap)2SO2Cl]•+ + Cl– }. Through this work, a more consistent and more complete conceptual framework has been developed to better understand this chemistry and how catalyst regeneration occurs. It is this important ground state process, which closes the catalytic cycle, and ultimately controls the enantioselectivity of ATRA reactions employing chiral copper photocatalysts

Investigating Competing Inner- and Outer-Sphere Electron-Transfer Pathways in Copper Photoredox-Catalyzed Atom-Transfer Radical Additions: Closing the Cycle.

This integrated computational and experimental study comprehensively examines the viability of competing inner-sphere electron transfer (ISET) and outer-sphere electron transfer (OSET) processes in [Cu(dap)2]+-mediated atom-transfer radical additions (ATRA) of olefins and CF3SO2Cl that can deliver both R-SO2Cl and R-Cl products. Five sterically- and electronically-varied representative alkenes were selected from which to explore and reconcile the range of experimentally observed outcomes. Findings are consistent with photoexcited [Cu(dap)2]+ initiating photoelectron transfer via ISETand the subsequent regeneration of the oxidized catalyst via single-electron transfer in the ground state via ISETto close the catalytic cycle and liberate products. R-SO2Cl/R-Cl product ratios appear to be primarily governed by the relative rates of direct catalyst regeneration {i.e., [Cu(dap)2SO2Cl]•+ + R•} and ligand exchange {i.e., [Cu(dap)2SO2Cl]•+ + Cl- }. Through this work, a more consistent and more complete conceptual framework has been developed to better understand this chemistry and how catalyst regeneration occurs. It is this important ground state process, which closes the catalytic cycle, and ultimately controls the enantioselectivity of ATRA reactions employing chiral copper photocatalysts.

DNA-Compatible Photoredox Atom Transfer Radical Addition to Alkynes with Thiosulfonates

DNA-Compatible Photoredox Atom Transfer Radical Addition to Alkynes with Thiosulfonates

Cu-Catalyzed Three-Component Alkene Carboamination: Mechanistic Insights and Rational Design to Overcome Limitations.

Herein, we report mechanistic investigations into the Cu-catalyzed three-component carboamination of alkenes with α-halo carbonyls and aryl amines via an oxocarbenium intermediate. Monitoring the reaction reveals the formation of transient atom transfer radical addition (ATRA) intermediates with both electron-neutral and deficient vinyl arenes as well as unactivated alkenes. Based on our experimental studies and density functional theory calculations, the oxocarbenium is generated through atom transfer and subsequent intramolecular substitution. Further, mechanistic factors that dictate the regioselectivity of the nucleophilic attack onto the oxocarbenium to afford the γ-amino ester, γ-iminolactone, or γ-lactone are discussed. A strategy to overcome scope limitation with respect to unactivated alkenes is developed using the mechanistic insights gained herein. Finally, we demonstrate that under modified conditions, our Cu catalyst enables the ATRA reaction between a variety of alkyl halides and vinyl arenes/α-olefins, and we present a one-pot, two-step carbofunctionalization with an array of nucleophiles through ATRA/SN2.

Visible Light‐Induced Cyanomethyl Radical Triggered Cascade Cyclization of Phenyl‐Linked 1,6‐Enynes with a‐Halogenated Acetonitriles

Photo‐promoted cyanomethyl radical procedures for the preparation of 2,3‐dihydro‐1H‐indenes and 2,8‐dihydrocyclopenta[a]indenes from phenyl‐linked 1,6‐enynes with α‐halogenated acetonitriles are reported. The iodocyanomethylation/cyclization is performed via an atom‐transfer radical addition (ATRA) strategy under photocatalyst‐ and oxidant‐free conditions. In particular, the photoinduced cyanomethylative cascade bicyclization is carried out under the fac‐Ir(ppy)3/Na2CO3 catalystic symtem and visible light irradiation. These methods offer a one‐step and atom‐economical access to diverse cyano‐group containing five‐membered rings with broad substrate scope and high selectivity. A plausible reaction mechanism is also proposed.

Photocatalyzed atom transfer radical addition: Halo-difluoroalkylation of N-allylamides

A method for the halo-difluoroalkylation of N-allylamides using XCF2CO2Et as the halo-difluoroalkylation reagent is disclosed. This strategy combines single electron transfer with atom transfer radical addition, using 1 mol% of the photocatalyst fac-Ir(ppy)3 without any additives to achieve conversions with high atom economy. The reaction proceeds smoothly in the presence of different active functional groups and is obtained in moderate to good yields.

Α Metal‐Free Photochemical Atom Transfer Radical Addition of CBr4 onto Alkenes as a Key Step for Their Conversion to Propargylamines

Α green and sustainable metal‐free photochemical protocol for the atom transfer radical addition (ATRA) of carbon tetrabromide onto alkenes was developed. Phenylglyoxylic acid was employed as the photoinitiator to promote the water‐mediated anti‐Markovnikov photochemical addition. A vast variety of alkenes was employed successfully, providing the corresponding products in good to high yields with excellent regioselectivity. The photochemical protocol found an application towards the three‐step synthesis of secondary or tertiary propargylamines starting from alkenes.

Access to β‐Lactam Sulfonamides from Sulfamoyl Chlorides via Photoredox Catalyzed C−S Bond Formation

AbstractSulfonyl chlorides are a synthetically attractive source of sulfonyl radicals in photoredox catalysis and are useful precursors in the synthesis of sulfones. Sulfamoyl chlorides, on the other hand, remain poorly represented despite their similar potential. In this study, N‐chlorosulfonylated β‐lactams were prepared from readily available precursors and utilized in an atom transfer radical addition (ATRA) reaction with a variety of olefins, producing β‐lactam sulfonamides in 49–95% yields. β‐Lactams fused to a dihydro‐1,2‐thiazine ring which closely resemble carbacephems, a widely used class of antibiotics, were also synthesized by an intra‐molecular ATRA reaction. This methodology enables the preparation of β‐lactam sulfonamides, a class of compounds that are of great interest in pharmacology.

Synthesis of 2,3-Dihydrobenzofurans via a Photochemical Gold-Mediated Atom Transfer Radical Addition Reaction.

A light-mediated cyclization reaction initiated by an atom transfer radical addition (ATRA) of haloalkanes onto alkenes was exploited for the synthesis of functionalized dihydrobenzofurans. Initial investigation indicated that the dimeric gold catalyst [Au2(μ-dppm)2Cl2] can effectively be used for intermolecular ATRA reactions. Further, the reactivity was applied in a cascade-like cyclization for the preparation of dihydrobenzofuran derivatives. With the presented photochemical approach, the functionalization can be achieved directly from ortho-allylphenols in yields of up to 96% under mild conditions.

Ketyl Radical Enabled Synthesis of Oxetanes

AbstractOxetanes, 4-membered oxygen-containing heterocycles, were identified to have pharmaceutical applications after the discovery of the chemotherapeutic drug taxol (Paclitaxel) and its analogues. Furthermore, oxetanes have been identified as bioisosteres for several common functional groups and are present in a number of natural products. However, oxetanes are one of the least common oxygen-containing heterocycles in active pharmaceutical ingredients on the market, which can be attributed, in part, due to challenges with their synthesis. Previous strategies rely on nucleophilic substitutions or [2+2]-cycloadditions, but are limited by the stepwise buildup of starting material and limitations in scope resulting from requirements for activated substrates. To address these limitations, we envisioned activating simple carbonyls to their corresponding α-oxy iodides to promote ketyl radical formation. These radicals can then undergo atom-transfer radical addition with alkenes followed by one-pot nucleophilic substitution to produce oxetanes. Herein, we present a proof-of-principle of this strategy in which fluoroalkyl carbonyls are successfully converted into the corresponding fluoroalkyl oxetanes.

Halogen-Bonding-Enabled Photoinduced Atom Transfer Radical Addition/Cyclization Reaction Leading to Tricyclic Heterocycles.

Atom transfer radical addition (ATRA) reactions are crucial for the dual functionalization of unsaturated hydrocarbons. Radical generation, pivotal in ATRA, has seen advancements from thermal to photochemical methods. Recent focus on halogen-bonding-based radical generation, including our group's innovative photochemical approach, offers cost-effective alternatives to transition-metal-dependent photocatalysts. This eliminates the need for high-energy UV light, enhancing the efficiency with noncovalent interactions.

Macrocyclic Copper(II) Complexes as Catalysts for Electrochemically Mediated Atom Transfer.

Copper-catalyzed electrochemical atom transfer radical addition (eATRA) is a new method for the creation of new C-C bonds under mild conditions. In this work, we have explored the reactivity of an analogous series of N4 macrocyclic CuII complexes as eATRA precatalysts, which are primed by reduction to their monovalent oxidation state. These complexes were fully characterized structurally, spectroscopically, and electrochemically. A spectrum of radical activation reactivity was found across the series [CuI(Me4cyclen)(NCMe)]+ (Me4cyclen = 1,4,7,10-tetramethyl-1,4,7,10-tetraazacyclododecane), [CuI(Me4cyclam)(NCMe)]+ (Me4cyclam = 1,4,8,11-tetramethyl-1,4,8,11-tetraazacyclotetradecane), and [CuI(Me2py2clen)(NCMe)]+ (Me2py2clen = 3,7-dimethyl-3,7-diaza-1,5(2,6)-dipyridinacyclo-octaphane). The rate of radical production by [Cu(Me2py2clen)(NCMe)]+ was modest, but rapid radical capture to form the organocopper complex [CuI(Me2py2clen)(CH2CN)] led to a dramatic acceleration in catalysis, greater than seen in any comparable Cu complex, but this led to rapid radical self-termination instead of radical addition.

Modulating β-Keto-enamine-Based Covalent Organic Frameworks for Photocatalytic Atom-Transfer Radical Addition Reaction.

The atom-transfer radical addition (ATRA) reaction simultaneously forges carbon-carbon and carbon-halogen bonds. However, frequently-used photosensitizers such as precious transition metal complexes, or organic dyes have limitations in terms of their potential toxicity and recyclability. Three β-ketoenamine-linked covalent organic frameworks (COFs) from 1,3,5-triformylphloroglucinol and 1,4-phenylenediamines with variable transient photocurrent and photocatalytic activity have been prepared. A COF bearing electron-deficient Cl atoms displayed the highest photocatalytic activity toward the ATRA reaction of polyhalogenated alkanes to give halogenated olefins under visible light at room temperature. This heterogeneous photocatalyst exhibited good functional group tolerance and could be recycled without significant loss of activity.

Atom Transfer Radical Addition of Activated Primary Alkyl Chlorides Using In Situ Generated [Cp*RuII(Cl)(PR3)] Catalysts

AbstractAtom transfer radical addition (ATRA) of halogenated compounds with alkenes is well established but primary alkyl chlorides are understudied because of the difficult C−Cl bond activation. In this paper, we show that TONs of 61 can be achieved in the ATRA of ethyl chloroacetate onto styrene with [Cp*Ru(Cl)2(PPh3)] and 1,1′‐azobis(cyclohexanecarbonitrile) (ACHN) as a radical initiator, representing a three‐fold improvement compared to previous reports. New catalyst precursors of the type [Cp*Ru(Cl)2(PR3)] were synthesized and tested (R=Me, Et, Cy, Ph, p‐CF3C6H4 and p‐MeOC6H4). The kinetic reaction profiles were studied using in situ ATR−FTIR spectroscopy. Among these complexes, [Cp*Ru(Cl)2(PPh3)] gave the best yields while [Cp*Ru(Cl)2(PMe3)] showed the highest rate. While rates correlate with redox potentials (electronics), our investigation reveals that substrate sterics are important for the overall yield. Density functional theory calculations suggest an open‐shell singlet pathway, where polymerization is kinetically disfavored, explaining the selectivity towards ATRA products.

Photochemical Synthesis of Lactones, Cyclopropanes and ATRA Products: Revealing the Role of Sodium Ascorbate.

Light-mediated processes have received significant attention, since they have re-surfaced unconventional reactivity platforms, complementary to conventional polar chemistry. γ-Lactones and cyclopropanes are prevalent moieties, found in numerous natural products and pharmaceuticals. Among various methods for their synthesis, light-mediated protocols are coming to the spotlight, although these are contingent upon the use of photoorgano- or metal-based catalysts. Herein, we introduce a novel photochemical activation of iodo-reagents via the use of cheap sodium ascorbate or ascorbic acid to enable their homolytic scission and addition onto double bonds. The developed protocol was applied successfully to the formal [3+2] cycloaddition for the synthesis of γ-lactones, traditional atom transfer radical addition (ATRA) reactions and the one-pot two-step conversion of alkenes to cyclopropanes. In all cases, the desired products were obtained in good to high yields, while the reaction mechanism was thoroughly investigated. Depending on the nature of the iodo-reagent, a halogen or a hydrogen-bonded complex is formed, which initiates the process.