Visible‐Light‐Mediated Generation of Nitrogen‐Centered Radicals: Metal‐Free Hydroimination and Iminohydroxylation Cyclization Reactions

Davies, Jacob; Booth, Samuel G.; Essafi, Stéphanie; Dryfe, Robert A. W.; Leonori, Daniele

doi:10.1002/ange.201507641

Cited by 118 publications

(24 citation statements)

References 74 publications

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“…Neben Anilinderivaten werden auch 3-Aminopyridin und Sulfonamide umgesetzt. Leonori und Mitarbeiter entwickelten eine photokatalytische Synthese von fünfgliedrigen N-Heterocyclen aus O-Aryloximen [98] und elektronenarmen Aryloxyamiden [99] als Vorstufen von stickstoffzentrierten Radikalen (siehe SI, Schema S7). [91] Ausgehend von 2-Halogenanilinen und Alkenen war die Kombination von Photoredoxkatalyse mit Nickelkatalyse entscheidend fürd ie Vermeidung der b-Hydrideliminierung (Bildung von Heck-Produkten) zugunsten der reduktiven Eliminierung der C-N-Bindung, die die gewünschten Indoline liefert.…”

Section: C-n-bindungsbildungunclassified

Photokatalyse mit sichtbarem Licht: Welche Bedeutung hat sie für die organische Synthese?

et al. 2018

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Die Photokatalyse mit sichtbarem Licht hat sich im letzten Jahrzehnt zu einer breit angewandten Methode in der organischen Synthese entwickelt. Für viele wichtige Reaktionen, wie Kreuzkupplungen, α‐Amino‐Funktionalisierungen, Cycloadditionen, ATRA‐Reaktionen oder Fluorierungen, wurden photokatalytische Varianten berichtet. Um Chemiker bei der Auswahl photokatalytischer Methoden für ihre Synthesen zu unterstützen, vergleichen wir in diesem Aufsatz klassische und photokatalytische Verfahren für ausgewählte Reaktionsklassen und zeigen deren Vorteile und Grenzen auf. In vielen Fällen verlaufen die photokatalytischen Reaktionen unter milderen Reaktionsbedingungen, typischerweise bei Raumtemperatur, und stöchiometrische Reagenzien werden durch einfache Oxidanzien oder Reduktionsmittel wie Luft, Sauerstoff oder Amine ersetzt. Beeinflusst die Photokatalyse mit sichtbarem Licht die organische Synthese? Die Aussicht, Elektronen zu Substraten und Zwischenprodukten hin‐ und herzuschieben oder Energie selektiv durch einen sichtbares Licht absorbierenden Photokatalysatoren zu übertragen, verspricht die aktuellen Verfahren in der Radikalchemie zu verbessern und neue Wege durch den Zugang zu reaktiven, bisher unbekannten Spezies zu erschließen, insbesondere durch das Zusammenspiel von Photokatalyse mit der Organo‐ oder Metallkatalyse.

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Section: C-n-bindungsbildungunclassified

Photokatalyse mit sichtbarem Licht: Welche Bedeutung hat sie für die organische Synthese?

et al. 2018

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“…[15] While successful, these reactions have not been employed in mainstream organic synthesis owing to three main limitations:1 )the aromatic compound is ac o-solvent (10-20 equiv);2 )high-energy light (l < 280 nm) is required and 3) the reactions are run in refluxing AcOH/H 2 SO 4 . [15c] We recently developed av isible-light-mediated synthesis of iminyl [16] and amidyl [11c] radicals through reductive SET fragmentation of electron-poor O-aryl oximes and aryloxyamides.W ee nvisaged that such an approach might have enabled access to aminium radicals for direct aromatic amination. In this paper we describe our work in the area that has resulted in ap owerful method for the fast construction of aryl amines (Scheme 1C).…”

Section: Buchwald-hartwigmentioning

confidence: 99%

“…We recently developed av isible-light-mediated synthesis of iminyl [16] and amidyl [11c] radicals through reductive SET fragmentation of electron-poor O-aryl oximes and aryloxyamides.W ee nvisaged that such an approach might have enabled access to aminium radicals for direct aromatic amination. In this paper we describe our work in the area that has resulted in ap owerful method for the fast construction of aryl amines (Scheme 1C).…”

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confidence: 99%

Synthesis of Arylamines via Aminium Radicals

et al. 2017

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Arylamines constitute the core structure of many therapeutic agents,a grochemicals,a nd organic materials.T he development of methods for the efficient and selective construction of these structural motifs from simple building blocks is desirable but still challenging.W ed emonstrate that protonated electron-poor O-aryl hydroxylamines give aminium radicals in the presence of Ru(bpy) 3 Cl 2 .T hese highly electrophilic species undergo polarized radical addition to aromatic compounds in high yield and selectivity.W es uccessfully applied this method to the late-stage modification of chiral catalyst templates,t herapeutic agents,and natural products.N,N-Dialkyl arylamines are ap rivileged scaffold found in blockbuster drugs,a grochemicals,a nd organic materials (Scheme 1A).[1] These molecular frameworks are usually assembled through Pd 0 -o rC u I/II -catalysed cross-couplings of amine nucleophiles and aryl halides (i.e., Ullmann [2] and Buchwald-Hartwig [3] coupling reactions) or arylboronic acids (i.e., Chan-Lam coupling [4] ).[5] However,t hese approaches require the use of sometimes expensive catalysts,f orcing reaction conditions,a nd pre-functionalized aromatics.T his latter aspect can be problematic when the aromatic partner is difficult to make or the introduction of halides or B functionalities suffers from directionality issues (ortho vs. meta vs. para). As such, methods for the direct amination of unfunctionalized aromatic compounds are very desirable but far from being general. [6] Nitrogen radicals [7] are highly reactive species that are now witnessing aresurgence of synthetic interest owing to the ability of photoredox catalysis [8] to promote single-electron transfer (SET) [9] processes under mild conditions.[10] While highly electrophilic amidyl [11] and sulfamidyl radicals [12] have been successfully coupled with highly electron-rich aromatic compounds (e.g.,i ndole,p yrrole), the use of dialkyl-substituted nitrogen radicals (aminyl radicals) in related arylations has yet to be described. This lack of synthetic application can be explained by the intrinsic nucleophilic nature of aminyls, which causes repulsive interactions between their lone pair and the aromatic ring.[13] However,upon protonation, aminyl radicals are converted into aminium radicals [10d,i,14] that are isoelectronic to alkyl radicals but carry af ormal positive charge (Scheme 1B). This makes them powerful electrophiles that undergo highly polarized radical processes.I ndeed, pioneering work from Minisci and co-workers showed that N À Cl amines can be arylated upon photochemical N À Cl bond homolysis.[15] While successful, these reactions have not been employed in mainstream organic synthesis owing to three main limitations:1 )the aromatic compound is ac o-solvent (10-20 equiv);2 )high-energy light (l < 280 nm) is required and 3) the reactions are run in refluxing AcOH/H 2 SO 4 .[15c]We recently developed av isible-light-mediated synthesis of iminyl [16] and amidyl [11c] radicals through reductive SET fragmentation o...

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“…form an electron-donor complex in solution,w hereby an electron-transfer event can be triggered by the near-UV/shorter wavelengths of blue visible light typicallyu sed in photoredox experiments. [18] Finally,w hen the reaction (conditions as Ta ble 1, entry 7) wass ubjected to three equivalents of TEMPO ((2,2,6,6-tetramethylpiperidin-1-yl)oxyl, the reaction failed to yield 10 a,s upporting the postulated radical character of the mechanism. Based on these results, we propose the pathway in Scheme 3f or the reaction, beginning with TMEDAphotoreduction of bromodifluoroacetate 6 to the radical 13.I ntermolecular addition gives the alkyl radical 8,whichcan undergo Truce-Smiles aryl shift with extrusiono fS O 2 .T he resultant amidyl radical 14 can then undergo hydrogen atom transfer,l ikely from the TMEDA which is present in excess, to yield the C-arylated product 9.…”

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Alkene Carboarylation through Catalyst‐Free, Visible Light‐Mediated Smiles Rearrangement

Whalley

Duong

Greaney

2019

Chemistry A European J

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A light‐mediated Truce–Smiles arylative rearrangement is described that proceeds in the absence of any photocatalyst. The protocol creates two C−C bonds from simple starting materials, with the installation of an aryl ring and a difluoroacetate moiety across unactivated alkenes. The reaction proceeds via a radical mechanism, utilizing a light‐mediated reduction of ethyl bromodifluoroacetate by N,N,N′,N′‐tetramethylethylenediamine (TMEDA) to set up intermolecular addition to an unactivated alkene, followed by Truce–Smiles rearrangement.

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Visible‐Light‐Mediated Generation of Nitrogen‐Centered Radicals: Metal‐Free Hydroimination and Iminohydroxylation Cyclization Reactions

Cited by 118 publications

References 74 publications

Photokatalyse mit sichtbarem Licht: Welche Bedeutung hat sie für die organische Synthese?

Photokatalyse mit sichtbarem Licht: Welche Bedeutung hat sie für die organische Synthese?

Synthesis of Arylamines via Aminium Radicals

Alkene Carboarylation through Catalyst‐Free, Visible Light‐Mediated Smiles Rearrangement

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