Photoredox Cyanomethylation of Indoles: Catalyst Modification and Mechanism

O’Brien, Connor; Droege, Daniel G; Jiu, Alexander Y; Gandhi, Shivaani; Paras, Nick A.; Olson, Steven H.; Conrad, Jay C.

doi:10.1021/acs.joc.8b01146

Cited by 42 publications

(32 citation statements)

References 48 publications

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“…ver the past decade, transition metal complexes (1)(2)(3) and organic dyes (4,5) have been investigated extensively as visible light-absorbing catalysts in a wide range of photoredox transformations (4,6). Nonetheless, their use is restricted on account of incompatibility with strong acidic or basic reaction media (7), strong nucleophiles, electrophiles, or reactive radical intermediates (4) exemplified by fac-Ir(ppy) 3 , which reacts with C(sp 3 ) radicals, leading eventually to catalyst deactivation (8,9). The photophysical properties of organic photocatalysts, such as eosin Y, drastically change with changing pH of the solution (7), and acridinium, triarylpyryliums, and quinolinium dyes are deactivated in the presence of nucleophiles such as amines, acetates, phosphates, or cyanide ions (4,10,11).…”

mentioning

confidence: 99%

Organic semiconductor photocatalyst can bifunctionalize arenes and heteroarenes

Ghosh

Khamrai

Savateev

et al. 2019

Science

474

361

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Photoexcited electron-hole pairs on a semiconductor surface can engage in redox reactions with two different substrates. Similar to conventional electrosynthesis, the primary redox intermediates afford only separate oxidized and reduced products or, more rarely, combine to one addition product. Here, we report that a stable organic semiconductor material, mesoporous graphitic carbon nitride (mpg-CN), can act as a visible-light photoredox catalyst to orchestrate oxidative and reductive interfacial electron transfers to two different substrates in a two- or three-component system for direct twofold carbon–hydrogen functionalization of arenes and heteroarenes. The mpg-CN catalyst tolerates reactive radicals and strong nucleophiles, is straightforwardly recoverable by simple centrifugation of reaction mixtures, and is reusable for at least four catalytic transformations with conserved activity.

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mentioning

confidence: 99%

Organic semiconductor photocatalyst can bifunctionalize arenes and heteroarenes

Ghosh

Khamrai

Savateev

et al. 2019

Science

474

361

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“…This results in a reduction of the manganese oxide on the surface of the final sludge catalyst, and a reduction in the active sites. As a result, the catalytic activity of the catalyst is low [32]. …”

Section: Resultsmentioning

confidence: 99%

Application of Plasma Treatment in Preparation of Soybean Oil Factory Sludge Catalyst and Its Application in Selective Catalytic Oxidation (SCO) Denitration

Zhang

Yang

et al. 2018

Materials

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At present, the most commonly used denitration process is the selective catalytic reduction (SCR) method. However, in the SCR method, the service life of the catalyst is short, and the industrial operation cost is high. The selective catalytic oxidation absorption (SCO) method can be used in a low temperature environment, which greatly reduces energy consumption and cost. The C/N ratio of the sludge produced in the wastewater treatment process of the soybean oil plant used in this paper is 9.64, while the C/N ratio of the sludge produced by an urban sewage treatment plant is 10–20. This study shows that the smaller the C/N ratio, the better the denitration efficiency of the catalyst. Therefore, dried oil sludge is used as a catalyst carrier. The influence of different activation times, and LiOH concentrations, on catalyst activity were investigated in this paper. The denitration performance of catalysts prepared by different activation sequences was compared. The catalyst was characterized by Fourier Transform infrared spectroscopy (FTIR), X-ray diffraction (XRD), X-ray photoelectron spectroscopy (XPS), and scanning electron microscope (SEM). The experimental results showed that: (1) When the concentration of the LiOH solution used for activation is 15%, and the activation time is four hours, the denitration effect of the catalyst is the best; (2) the catalyst prepared by activation before plasma roasting has the best catalytic activity.

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“…Conrad and co‐workers developed a photoredox catalyzed direct cyanoalkylation of indoles at the 2‐position to give functionalized indoles (Scheme 48). [77] As for the reaction mechanism, bromoacetonitrile is reduced to radical anion by excited state Ir (III) * via single‐electron transfer, which is converted to acetonitrile radical 136 and bromide anion by decomposition. Then, electron‐deficient radical 136 reacts with electron‐rich indoles to give radical intermediate 137 .…”

Section: Photo‐catalyzed/promoted Functionalization Of Indole Derivatmentioning

confidence: 99%

Recent Developments in Photo‐Catalyzed/Promoted Synthesis of Indoles and Their Functionalization: Reactions and Mechanisms

2020

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The use of clean and renewable light sources is increasingly common in organic synthesis due to its safety, practicality and economy. Recently, photoredox catalysis has shown great application values in organic transformations because of its advantages of environmentally friendly and abundant resources. Indoles and their derivatives (indolines, oxindoles and isatins) are the core skeletons of some important organic compounds and widely‐present in various natural products and pharmaceuticals with different biological activities. Therefore, the research on the synthesis and modification of indoles is particularly important for chemists and pharmacologists. This review summarizes the effects of photocatalysis on indole synthesis and modification in recent decades. These transformations are accomplished by using metal photocatalysts (i. e., Ir, Ru, Ni, Cu, Fe, Au, Rh, TiO2, etc.) or non‐metallic photocatalysts (i. e., Rose Bengal, Eosin Y, quinones, naphthols, N‐heterocyclic carbenes, carbazoles, pyrylium salts, etc.), or without the need of photocatalysts. The detailed mechanisms of these photo‐catalyzed/promoted organic reactions are also highlighted deeply. And we hope this review will be helpful to researchers interested in this promising field of photocatalyzed transformations.

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Photoredox Cyanomethylation of Indoles: Catalyst Modification and Mechanism

Cited by 42 publications

References 48 publications

Organic semiconductor photocatalyst can bifunctionalize arenes and heteroarenes

Organic semiconductor photocatalyst can bifunctionalize arenes and heteroarenes

Application of Plasma Treatment in Preparation of Soybean Oil Factory Sludge Catalyst and Its Application in Selective Catalytic Oxidation (SCO) Denitration

Recent Developments in Photo‐Catalyzed/Promoted Synthesis of Indoles and Their Functionalization: Reactions and Mechanisms

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