Rates of Hydroxide Decomposition of Cyclic Phosphonium Salts

Cremer, Sheldon E.; Trivedi, B. C.; Weitl, Frederick L.

doi:10.1021/jo00820a601

Cited by 15 publications

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“…Thus, for example, Pbenzylphosphetanium bromides are hydrolyzed to the corresponding oxides 10 4 times faster than analogous phospholanium bromides. 150 This reflects relief of ring strain in the intermediate phosphorane. Ring strain also accelerates the alkaline hydrolysis of phosphinate esters (10 2 times faster than acyclic analogues).…”

Section: Stereochemistry Of the Nucleophilic Substitutions On Phosphementioning

confidence: 96%

“…It is noteworthy that alkaline hydrolysis rates for cyclic phosphonium salts increase significantly upon moving from large ring or acyclic compounds to smaller ring compounds. Thus, for example, P -benzylphosphetanium bromides are hydrolyzed to the corresponding oxides 10 4 times faster than analogous phospholanium bromides . This reflects relief of ring strain in the intermediate phosphorane.…”

Section: Stereochemistry Of the Nucleophilic Substitutions On Phosphe...mentioning

confidence: 98%

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Synthesis and Properties of Phosphetanes

Marinetti

Carmichael

2002

Chem. Rev.

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Section: Stereochemistry Of the Nucleophilic Substitutions On Phosphementioning

confidence: 96%

Section: Stereochemistry Of the Nucleophilic Substitutions On Phosphe...mentioning

confidence: 98%

Synthesis and Properties of Phosphetanes

Marinetti

Carmichael

2002

Chem. Rev.

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“…Evidently, direct uncatalyzed reduction of 3 with LiAlH(O t Bu) 3 outcompetes notional biphilic catalysis by triphenylphosphine. Following on Gallagher’s hypothesis and abundant precedent demonstrating enhanced electrophilic reactivity of cyclic phosphorus-based compounds compared to their acyclic congeners, the conversion σ 4 -P + → σ 5 -P was targeted for acceleration. While neither dibenzophosphole 8 nor phospholane 9 derivatives (proven catalyst motifs in several catalytic P III /P V O redox methods) satisfactorily alter the reduction outcome, catalytic loading of phosphonium salt derived from a four-membered phosphetane 10 , delivers reduction products with excellent γ/α-selectivity.…”

mentioning

confidence: 99%

Biphilic Organophosphorus Catalysis: Regioselective Reductive Transposition of Allylic Bromides via P^III/P^V Redox Cycling

et al. 2015

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We report that a regioselective reductive transposition of primary allylic bromides is catalyzed by a biphilic organophosphorus (phosphetane) catalyst. Spectroscopic evidence supports the formation of a pentacoordinate (σ5-P) hydridophosphorane as a key reactive intermediate. Kinetics experiments and computational modeling are consistent with a unimolecular decomposition of the σ5-P hydridophosphorane via a concerted cyclic transition structure that delivers the observed allylic transposition and completes a novel PIII/PV redox catalytic cycle. These results broaden the growing repertoire of reactions catalyzed within the PIII/PV redox couple and suggest additional opportunities for organophosphorus catalysis in a biphilic mode.

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“…As mentioned previously, P−C bond cleavage of five-membered cyclic phosphonium salts with various hydroxides, 78,79 producing the corresponding phosphine oxides, is a known reaction type. This suggests that compound 1 did not react with sodium methoxide, but rather slow formation of sodium hydroxide occurred in solution due to the presence of water, which in turn reacted with compound 1, cleaving one of the benzylic P−C bonds and producing compound 2.…”

Section: Cyclic Phosphonium Saltmentioning

confidence: 86%

“…This compound is similar to known cyclic dimethyl-and diphenyl-substituted phosphonium bromides. 76 Other than the treatment of these compounds with methylenetrimethylphosphorane 76 or potassium t-butoxide 77 to form cyclic phosphorus ylides, and P−C bond cleavage with various hydroxides, 78,79 the reactivity of these five-membered cyclic phosphonium salts has not been widely studied. The direct reaction of cyclic phosphonium bromide 1 with lithium metal in THF followed by quenching with water resulted largely in the recovery of unchanged starting material (Scheme 2.5).…”

Section: Cyclic Phosphonium Saltmentioning

confidence: 99%

Hybrid P,E Ligands: Synthesis, Coordination Chemistry and Catalysis

Allan¹

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<p>This thesis provides an account of research into a family of novel hybrid P,E ligands containing an o-xylene backbone. A methodology for the synthesis of these ligands has been developed, and their coordination behaviour with platinum(II) and platinum(0) precursors has been explored, with particular focus on a phosphinethioether (P,S) ligand of this type. The coordination modes of this P,S ligand with palladium precursors have also been investigated, and the utility of the ligand in a palladium and copper co-catalysed Sonogashira carbon-carbon bond-forming reaction has been evaluated. A range of hybrid P,E ligands of the type o-C₆H₄(CH₂PBut₂)(CH₂E) (E = PR₂, SR, S(O)But, NR₂, SiPh₂H) have been synthesised in two or three steps from the novel substrate, o-C₆H₄(CH₂PBut₂(BH₃)}(CH₂Cl). The initial step involved treatment of the substrate with the appropriate nucleophilic reagent, or preparation of a Grignard reagent from o-C₆H₄{CH₂PBut₂(BH₃)}(CH₂Cl) and reaction with the appropriate electrophile. In most cases, this versatile strategy produced air-stable crystalline ligand precursors. Phosphine deprotection was achieved via one of three methods, dependent upon the properties of the second functional group. The reactivity of three of these ligands — o-C₆H₄{CH₂PBut₂)(CH₂SBut) (14a), o-C₆H₄{CH₂PBut₂){CH₂S(O)But} (16) and o-C₆H₄(CH₂PBut₂)(CH₂NMe₂) (18a) — with Pt(II) and Pt(0) precursor complexes has been investigated. Chelated [PtCl₂(P,E)] complexes were synthesised with P,S ligand 14a and P,N ligand 18a, but attempts to produce the equivalent species with P,S=O ligand 16 were unsuccessful. The X-ray crystal structure of [PtCl₂(P,S)] complex 21 displayed an unexpectedly small ligand bite angle of 86.1°. A series of platinum(II) hydride complexes of the types [PtHL(P,S)₂] and [PtHL(P,S)₂]CH(SO₂CF₃)₂ (L = Cl¯, H¯, NCMe, −CH₂SBut , CO, pta) have been synthesised, where ligand 14a binds in a monodentate fashion through the phosphorus donor atom. This work has demonstrated the hemilability of ligand 14a, via the facile and reversible conversion between [PtH(κ¹P-14a)(κ²P,S-14a)]CH(SO₂CF₃)₂ (26) and [PtH(NCMe)(κ¹P-14a)₂]CH(SO₂CF₃)₂ (28). The X-ray crystal structure of [PtH₂(P,S)₂] complex 25 was used to calculate a cone angle of 180° for the phosphine moiety in ligand 14a. Reaction of P,S ligand 14a and P,S=O ligand 16 with [Pt(alkene)₃] complexes (alkene = ethene, norbornene) gave the chelated [Pt(alkene)(P,E)] complexes 32–35; however, under similar conditions a [Pt(norbornene)(P,N)] complex did not form. A large ligand bite angle of 106.6° was observed in the X-ray crystal structure of [Pt(norbornene)(P,S)] complex 34. Reaction of two equivalents of each of the P,E ligands with [Pt(norbornene)₃] gave the corresponding 14-electron linear complexes [Pt(P,E)₂] (36–38) with the ligands coordinated through the phosphorus donor atoms only. The reactivity of [Pt(norbornene)(P,S)] complex 34 and [Pt(P,S)₂] complex 36 has been investigated, resulting in the complexes [PtH{CH(SO₂CF₃)₂}(P,S)] (39), [Pt(norbornyl)(P,S)] (40), [Pt(ethyne)(P,S)] (41) and [Pt(O₂)(P,S)₂] (42). The reactivity of P,S ligand 14a was investigated with Pd(II) and Pd(0) precursors, resulting in the identification of five coordination modes of this ligand. Monodentate binding was observed in [Pd(P,S)₂] complex 44, and chelation in the [Pd(alkene)(P,S)] complexes 47 (alkene = norbornene) and 48 (alkene = dba). Reaction of ligand 14a with [PdCl₂(NCBut)₂] at raised temperature resulted in S−C bond cleavage and the formation of palladium dimer 43 with bidentate coordination of the ligand through phosphine and bridging thiolate moieties. Reaction of ligand 14a with [Pd(OAc)₂] resulted in C−H activation of the aryl backbone and formation of [Pd(μ-OAc)(P,C)]₂ dimer 46. In the presence of excess [Pd(OAc)₂], palladium hexamer 45 was formed, with a combination of P,C palladacycle and monodentate thioether binding resulting in bridging P,C,S coordination of ligand 14a. The Sonogashira cross-coupling of 4-bromoanisole and phenylethyne was performed with 3 mol% of a pre-catalyst mixture containing P,S ligand 14a, [Pd(OAc)₂] and CuI, resulting in quantitative conversion to 4-(phenylethynyl)anisole in four hours. Two enyne by-products were also identified from the reaction. Variations to the pre-catalyst mixture and catalyst loading indicated there was a significant ligand dependence on the yield and selectivity of the reactions. Mercury drop tests and dynamic light scattering experiments confirmed the presence of palladium nanoparticles in the reaction solution; however, the active catalytic species in these reactions has not been identified.</p>

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Rates of Hydroxide Decomposition of Cyclic Phosphonium Salts

Cited by 15 publications

References 0 publications

Synthesis and Properties of Phosphetanes

Synthesis and Properties of Phosphetanes

Biphilic Organophosphorus Catalysis: Regioselective Reductive Transposition of Allylic Bromides via P^III/P^V Redox Cycling

Hybrid P,E Ligands: Synthesis, Coordination Chemistry and Catalysis

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Rates of Hydroxide Decomposition of Cyclic Phosphonium Salts

Cited by 15 publications

References 0 publications

Synthesis and Properties of Phosphetanes

Synthesis and Properties of Phosphetanes

Biphilic Organophosphorus Catalysis: Regioselective Reductive Transposition of Allylic Bromides via PIII/PV Redox Cycling

Hybrid P,E Ligands: Synthesis, Coordination Chemistry and Catalysis

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Biphilic Organophosphorus Catalysis: Regioselective Reductive Transposition of Allylic Bromides via P^III/P^V Redox Cycling