<i>meso</i>-Tetraphenylporphyrin Iron Chloride Catalyzed Selective Oxidative Cross-Coupling of Phenols

Shalit, Hadas; Libman, Anna; Pappo, Doron

doi:10.1021/jacs.7b05898

Cited by 82 publications

(82 citation statements)

References 120 publications

(40 reference statements)

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“…This resultc an be explained by ac ompetitive inhibition of the catalystd ue to the coordination of HFIP to the catalyst. [20,30,31] Subsequently,w et ested the redox-activel igand 1 2 + + ,w hich was also used for phenol coupling [60] in aP CET reaction. In addition to the higher costs of HFIP,t he dramatic decrease in the reactionr ate led us explore an ovel concept that is not restricted to the use of this solvent.…”

Section: Chemoselectivity In the Cross-coupling Reactionsmentioning

confidence: 99%

“…In contrast,t he cross-coupling reaction is favored in ar adicalanion coupling mechanism of phenols with ac omplementary relationship (N B > N A ), leading to ad esired high cross-coupling chemoselectivity.O nt he other hand, phenols with an on-complementary relationship (N A > N B )g enerally display al ower cross-coupling chemoselectivity,e ven for ar adical-anion coupling mechanism. [31] This work relied on tert-BuOOH as the oxidizing reagent and HFIP as the solvent. [22,23] Kozlowski et al studied the aerobic cross-coupling of phenolsw ith ac omplementary relationship with different catalysts (namely,C r-salen complexes).…”

Section: Introductionmentioning

confidence: 99%

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Catalytic Aerobic Phenol Homo‐ and Cross‐Coupling Reactions with Copper Complexes Bearing Redox‐Active Guanidine Ligands

Schön

Kaifer

Himmel

2019

Chemistry A European J

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Due to their large importance in synthetic chemistry,c atalytic CÀCc oupling reactions of phenolsa re currently intensively studied. Herein, new copperc atalysts for the CÀC coupling reactiono fp henols using dioxygen as ag reen oxidizing reagent are reported. By using redox-active guanidine ligands, the activity as well as chemoselectivity in the cross-coupling reaction of non-complementary phenols( between an electron-rich phenol and al ess nucleophilic second phenol)i ss ignificantly improved. Based on the collected data for severalt est reactions,areaction mechanism is proposed.Scheme1.Flow-chartfor generalp rinciples in the phenol cross-coupling reactions. Adapted from Pappo et al. [20] [a] F.

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Section: Chemoselectivity In the Cross-coupling Reactionsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Catalytic Aerobic Phenol Homo‐ and Cross‐Coupling Reactions with Copper Complexes Bearing Redox‐Active Guanidine Ligands

Schön

Kaifer

Himmel

2019

Chemistry A European J

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“…[4] Oxidative functionalization of phenold erivatives, in contrast, alwaysr equiresp henols substituted by electron-donating groups, as well as blocking groups, to ensure ah igh degree of site selectivity. [5] Transition-metal-catalyzed selective CÀHa ctivation of phenol derivatives provides an alternative for the synthesis of functionalized phenols. In comparison to the above reactions, the directed CÀHa ctivationso fp henols generally have higher regio-and/orm onoselectivity.I na ddition, CÀHa ctivation at all positions aroundt he phenol ring (ortho, meta,a nd para)c an be achieved through directing-group and catalystc ontrol.…”

Section: Introductionmentioning

confidence: 99%

Transition Metal‐Catalyzed Directing‐Group‐Assisted C−H Activation of Phenols

Luo

2019

ChemSusChem

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Strategies that exploit directing groups to control the site selectivity in the C−H activation of arenes have received much attention during the past two decades. In light of the importance of phenol derivatives in the areas of pharmaceuticals, agrochemicals, and materials science, transition‐metal‐catalyzed C−H activation of phenols has proven to be an extremely useful tool in organic synthesis. This Minireview summarizes the current state‐of‐the‐art direct C−H activation of phenol derivatives under transition‐metal catalysis.

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“…An alternative synthetic approachw as published by Pappo and co-workers.T oa ccess the para-biphenols a meso-tetraphenylporphyrin iron chloride catalysta nd peroxidesa st he stoichiometrico xidant was employed. [12] Using peroxides as reagent is involving potential safety risks at least on technical-scale operations. [13] Moreover, these strategies create additional waste which has to be disposed upon synthesis.…”

mentioning

confidence: 99%

“…[18] The highest yield of 77 %w as obtained by using the electron rich 2,6-dimethoxyphenol as component A and 2-methyl-5-(1-methylethyl)phenol as component B (Scheme 2, 10). This underlines that as terically demanding substituent in position 5i sa blet op revent over-oxidationt o the corresponding diphenoquinone and therefore increases the yield of the desired 4,4'-biphenol.W hen switching the isopropyls ubstituent in position 5t oamethyl group, three more derivatives in good yields up to 62 %a re accessible (Scheme 2, molecules [11][12][13]. Installingafluoro group in position 5, there is ad rop in yield and the desired cross-coupling product 16 was isolated in only 10 %y ield.…”

mentioning

confidence: 99%

Selective Formation of 4,4′‐Biphenols by Anodic Dehydrogenative Cross‐ and Homo‐Coupling Reaction

Dahms

Kohlpaintner

Wiebe

et al. 2019

Chemistry A European J

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A simple and selective electrochemical synthesis by dehydrogenative coupling of unprotected 2,6‐ or 2,5‐substituted phenols to the desired 4,4′‐biphenols is reported. Using electricity as the oxidizing reagent avoids pre‐functionalization of the starting materials, since a selective activation of the substrates takes place. Without the necessity for metal‐catalysts or the use of stoichiometric reagents it is an economic and environmentally friendly transformation. The elaborated electrochemical protocol leads to a broad variety of the desired 4,4′‐biphenols in a very simplified manner compared to classical approaches. This is particular the case for the cross‐coupled products.

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meso-Tetraphenylporphyrin Iron Chloride Catalyzed Selective Oxidative Cross-Coupling of Phenols

Cited by 82 publications

References 120 publications

Catalytic Aerobic Phenol Homo‐ and Cross‐Coupling Reactions with Copper Complexes Bearing Redox‐Active Guanidine Ligands

Catalytic Aerobic Phenol Homo‐ and Cross‐Coupling Reactions with Copper Complexes Bearing Redox‐Active Guanidine Ligands

Transition Metal‐Catalyzed Directing‐Group‐Assisted C−H Activation of Phenols

Selective Formation of 4,4′‐Biphenols by Anodic Dehydrogenative Cross‐ and Homo‐Coupling Reaction

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