Reaction of Singlet Dioxygen with Phosphine–Borane Derivatives: From Transient Phosphine Peroxides to Crystalline Peroxoboronates

Porcel, S.; Bouhadir, Ghenwa; Saffon, Nathalie; Maron, Laurent; Bourissou, Didier

doi:10.1002/anie.201000520

Cited by 82 publications

(39 citation statements)

References 60 publications

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“…It was found, however, that phosphine-borane 1-Ph2P-2-Bcat-C6H4 (7) was also generated in the reaction conditions (Scheme 6). This family of phosphinoboranes is well known and several derivatives were previously reported by Bourissou and coworkers [39][40]. The independent synthesis of 7 did show that this species does not react with CO2 nor with catecholborane (Scheme 7).…”

Section: Ambiphilic Molecules As Catalysts For the Reduction Of Carbomentioning

confidence: 86%

Design principles in frustrated Lewis pair catalysis for the functionalization of carbon dioxide and heterocycles

Fontaine

Courtemanche

Légaré

et al. 2017

Coordination Chemistry Reviews

102

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This is the peer reviewed version of the following article: [Design Principles in Frustrated Lewis KeywordsFrustrated Lewis pairs, Ambiphilic molecules, Boron, Aluminum, Carbon dioxide, Methanol, C-H activation. Highlights 1.Phosphine-aluminum frustrated Lewis pairs (FLPs) can activate CO2 but show significant stability issues. 2.The Lewis acidity and basicity need to be fine-tuned to the desired reactivity for efficient FLP catalysis.3. FLP catalysts need to generate strong hydrides to reduce catalytically carbon dioxide. 4.Transition metal catalysis can serve as an inspiration for the design of metal-free catalysts for many transformations, including the borylation of heteroarenes. Graphical abstract AbstractThis account describes our work on the use of ambiphilic molecules as catalysts for the reduction of carbon dioxide. Starting with the discovery that aluminum ambiphilic species (Me2PCH2AlMe2)2 (1) and Al(C6H4-PPh3)3 (5) could coordinate CO2 but showed significant instability, we found that phosphinoborane Ph2P-2-Bcat-C6H4 (7) was an exceptional catalyst for the hydroboration of CO2 to methoxyboranes, a molecule that can be readily hydrolyzed to methanol. A mechanistic investigation allowed us to outline the similarities between the catalytic activity of frustrated Lewis pairs (FLPs) and that of transition metal complexes. We were able to extrapolate four important guidelines, described in this account, to synthesize efficient metal-free catalysts. We demonstrate that using these concepts it was possible to rationally design FLP catalysts for the C-H borylation of heteroarenes.

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Section: Ambiphilic Molecules As Catalysts For the Reduction Of Carbomentioning

confidence: 86%

Design principles in frustrated Lewis pair catalysis for the functionalization of carbon dioxide and heterocycles

Fontaine

Courtemanche

Légaré

et al. 2017

Coordination Chemistry Reviews

102

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“…[5] Ther eaction of triethylborane with triplet dioxygen is atypical example,which provides amethod of generating ethyl radicals. [6] Bourissou et al reported the addition/insertion reaction of singlet dioxygen to ap hosphane/ borane pair, [7] and there were several ways to form peroxy boron compounds that have been reported. [8] Agapie et al recently described the reduction of dioxygen by two molar equivalents of ferrocenes in the presence of the strong boron Lewis acid B(C 6 F 5 ) 3 to yield the bis(ferrocenium) bis(borane)peroxides 1a,b (Scheme 1).…”

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confidence: 99%

Reduction of Dioxygen by Radical/B(p‐C₆F₄X)₃ Pairs to Give Isolable Bis(borane)superoxide Compounds

et al. 2017

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Triplet dioxygen was reduced by TEMPO or trityl radicals in the presence of two molar equivalents of the strong B(p-C 6 F 4 X) 3 (X:For H) boron Lewis acids under mild conditions to give the bis(borane)superoxide systems 2.T he sensitive radical anion species were isolated and characterized by methods including X-ray crystal structure analysis and EPR spectroscopy.Supportinginformation and the ORCID identification number(s) for the author(s) of this article can be found under: https://doi.

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“…Selectedbondlengths []a nd angles [8]for 2a:P1 ÀC221.8179(11), C22À C23 1.5400(15), C23ÀO1 1.4068(13), C23ÀC24 1.5220(15), O1ÀB1 1.4909 (14), B1ÀC1 1.7023(16), C1ÀP1 1.7934(11);P1-C1-B11 15.77 (7),P 1-C22-C23 110.36 (7), C22-C23-O1107.78(9), C23-O1-B11 15.06(8). 2b:P1 ÀC22 1.8228 (12), C22ÀC231 .5479 (15),C 23ÀO1 1.4040 (14), C23ÀC241.5223(16), O1ÀB1 1.4838(15), B1ÀC1 1.6924(17), C1ÀP1 1.7872 (12);P1-C1-B1 115.77(8), P1-C22-C23 113.34(8), C22-C23-O1 110.02(9), C23-O1-B1 117.07(9).…”

Section: Resultsmentioning

confidence: 99%

“…The molecular structure of 3a is unambiguously established by single-crystal X-ray diffraction analysis (Figure 3, bottom) [24] and shows that the ring-opened 2-methyloxirane gives rise to Scheme3.Relative wB97X-D/6-31G(d,p) Gibbs free energies (in kcal mol À1 )for the conversion of 1 into 2a-c (only the methyl-substituted species a are shown;hydrogen atoms are omitted for clarity). (17),C22ÀC23 1.538(2),C 23ÀO1 1.403(2), C23ÀC24 1.532(2), O1ÀB1 1.519(2), C1ÀP1 1.7956 (19);P1-C22-C23 118.56 (12), C22-C23-O1 107.67 (15), C23-O1-B1119.77 (14).…”

Section: Resultsmentioning

confidence: 99%

“…[1] Accordingly,t he combination of aL ewis acid andaLewis base, whicha re sterically prevented from forming ac lassical Lewis acid-base adduct, allows the activation of av ariety of small molecules, [2] including dihydrogen, [2,3] olefins, [4] alkynes, [5] CO 2 , [6] SO 2 , [7] NO, [8] CO, [9] N 2 O, [10] isocyanates, azides, [11] as well as singlet dioxygen. [12] Moreover,F LPs are also able to ring-open cyclic substrates. Stephan and co-workers showedt hat phosphine/borane [13] or amine/borane [14] combinations induce ring-opening of THF,w hile Ta mm's group dem-onstrated that N-heterocyclic carbenes (NHCs) as Lewis bases can cleave THF in the presence of the highlye lectron-deficient tris(pentafluorophenyl)borane (B(C 6 F 5 ) 3 )a ffording in all cases zwitterionic species of type A (Figure 1).…”

Section: Introductionmentioning

confidence: 99%

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Ring‐opening of Epoxides Mediated by Frustrated Lewis Pairs

Krachko

Nicolas

Ehlers

et al. 2018

Chemistry A European J

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Treatment of the preorganized frustrated Lewis pairs (FLPs) tBu PCH BPh (1) and o-Ph P(C H )BCat (Cat=catechol) (4) with 2-methyloxirane, 2-phenyloxirane and 2-(trifluoromethyl)oxirane resulted in epoxide ring-opening to yield the six- and seven-membered heterocycles 2 a-c and 5 a-c, respectively. These zwitterionic products were characterized spectroscopically, and compounds 2 a, 2 b, 5 a and 5 c were structurally characterized by single-crystal X-ray structure analyses. Based on computational and kinetic studies, the mechanism of these reactions was found to proceed via activation of the epoxide by the Lewis acidic borane moiety followed by nucleophilic attack of the phosphine of a second FLP molecule. The resulting chain-like intermediates afford the final cyclic products by ring-closure and concurrent release of the second equivalent of FLP that behaves as catalyst in this reaction.

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Reaction of Singlet Dioxygen with Phosphine–Borane Derivatives: From Transient Phosphine Peroxides to Crystalline Peroxoboronates

Cited by 82 publications

References 60 publications

Design principles in frustrated Lewis pair catalysis for the functionalization of carbon dioxide and heterocycles

Design principles in frustrated Lewis pair catalysis for the functionalization of carbon dioxide and heterocycles

Reduction of Dioxygen by Radical/B(p‐C₆F₄X)₃ Pairs to Give Isolable Bis(borane)superoxide Compounds

Ring‐opening of Epoxides Mediated by Frustrated Lewis Pairs

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Reaction of Singlet Dioxygen with Phosphine–Borane Derivatives: From Transient Phosphine Peroxides to Crystalline Peroxoboronates

Cited by 82 publications

References 60 publications

Design principles in frustrated Lewis pair catalysis for the functionalization of carbon dioxide and heterocycles

Design principles in frustrated Lewis pair catalysis for the functionalization of carbon dioxide and heterocycles

Reduction of Dioxygen by Radical/B(p‐C6F4X)3 Pairs to Give Isolable Bis(borane)superoxide Compounds

Ring‐opening of Epoxides Mediated by Frustrated Lewis Pairs

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Reduction of Dioxygen by Radical/B(p‐C₆F₄X)₃ Pairs to Give Isolable Bis(borane)superoxide Compounds