Imide--amide rearangement of cylic phosphorimidates: a mechanistic study

Studies aimed at the development of new synthetic pathways for the preparation of chiral cyclic oxaza and diaza phosphoramides suitable for use in asymmetric chemistry led us to the investigation of the imide -amide rearrangement of cyclic phosphorimidates. As a result of this work new types of oligomeric organophosphorus compounds, formed by a novel 1,4-addition type ring opening polymerisation, were identified. These compounds are the stable intermediates of the imide-amide rearrangement, which upon heating yield the previously reported rearranged product. A detailed study of the mechanism of the Lewis acid catalysed imide-amide rearrangement and stereochemical control of the final products is reported. As a result, the full mechanism was elucidated and evidence of retention of configuration at the rearranged carbon atom is presented. Substituent effects were rationalised based on molecular modelling calculations.     

Pushing the Lewis Acidity Boundaries of Boron Compounds With Non‐Planar Triarylboranes Derived from Triptycenes

Bending the planar trigonal boron center of triphenylborane by connecting its aryl rings with carbon or phosphorus linkers gave access to a series of 9‐boratriptycene derivatives with unprecedented structures and reactivities. NMR spectroscopy and X‐ray diffraction of the Lewis adducts of these non‐planar boron Lewis acids with weak Lewis base revealed particularly strong covalent bond formation. The first Lewis adduct of a trivalent boron compounds with the Tf₂N^? anion illustrates the unrivaled Lewis acidity of these species. Increasing the pyramidalization of the boron center and using a cationic phosphonium linker resulted in an exceptional enhancement of Lewis acidity. Introduction of a phosphorus and a boron atom at each edge of a triptycene framework, allowed access to new bifunctional Lewis acid‐base 9‐phospha‐10‐boratriptycenes featuring promising reactivity for the activation of carbon‐halogen bonds.     

The Stereochemical Course of the α‐Hydroxyphosphonate–Phosphate Rearrangement

The phosphonate–phosphate rearrangement is an isomerisation of α‐hydroxyphosphonates bearing electron‐withdrawing substituents at the α‐carbon atom. We studied the stereochemical course of this rearrangement with respect to phosphorus. A set of four diastereomeric α‐hydroxyphosphonates was prepared by a Pudovik reaction from two diastereomeric cyclic phosphites. The hydroxyphosphonates were separated and rearranged with Et₃N as base. In analogy to trichlorphon, which was the first reported compound undergoing this rearrangement. All four hydroxyphosphonates could be rearranged to 2,2‐dichlorovinyl phosphates. Single‐crystal X‐ray structure analyses of the α‐hydroxyphosphonates and the corresponding phosphates allowed us to show that the rearrangement proceeds with retention of configuration on the phosphorus atom.     

Studies on the Imide-Amide Rearrangement of Cyclic Phosphorimidates

Abstract

The imide-amide rearrangement of cyclic phosphorirnidates 1 leads to the formation of phosphoramidates 3, either thermally (> 180°C) or by the action of a Lewis acid (BF₃ OEt₂, 60°C)¹. In an attempt to develop a synthetic pathway to β aminoalcohols based on this rearrangement, we have thoroughly studied the influence of the structure of the reactants on the Lewis acid catalysed rearrangement. This study brought some insight into the mechanism of this particular reaction, namely the identification of a new polymeric structure 2. not yet described, which is converted into 3 by thermolysis². The formation of 2 at rt was followed by ³ P NMR. In the case of R′? Ph, the reactivity observed for R₂N was: i-Pr₂N > Pyrrolidine > n-Bu²N For R²=i-Pr₂, the observed R′ group effect was: Bn > 4-NO₂Bn > Ph. No reaction was observed for R′ ? Ts, n-Oct. In the case of the groups R′ ? Bn and R₂=i Pr₂ the Lewis acid effect was also studied: BF₃OEt₂, BF₃MeOr-Bu, Sc(OTf)₃ or CITi(Oi-Pr)₃ or Me₂SnCl₂.     

Diastereoselective addition of α-substituted α-amino-H-phosphinates to imines using Yb(OTf)3 as an efficient Lewis acid catalyst

Diastereoselective addition of α-substituted α-amino-H-phosphinates to imines is described. Among Lewis acids, Yb(OTf)₃ was found to be the best catalyst. α,α′-Diaminophosphinic derivatives were obtained with de's ranging from 10 to 95% in the presence of Yb(OTf)₃ as an efficient Lewis acid catalyst. The reaction proceeded with retention of configuration at the phosphorus atom.     

Stereoselective reactions of trivalent phosphorus compounds

The data on stereoselective reactions of achiral compounds of trivalent phosphorus with chiral nucleophiles (derivatives of secondary alcohols, amines, and amino acids) are analyzed and discussed. In certain cases, these reactions enable preparation of optically active aminophosphines and phosphinites, precursors in the synthesis of chiral organophosphorus compounds and phosphine ligands. The reactions are suitable for elucidation of mechanism and stereochemistry of nucleophilic substitution at trivalent phosphorus atom.     

Complexes of imidophosphoric compounds with BF3

IR,³¹P NMR and¹⁹F NMR spectroscopy was used to study triphenylphosphinimines with substituants at the nitrogen atom and their complexes with boron trifluoride. In the case of aryl or benzyl substituants, BF₃ adds to the nitrogen atom, while the state of the phosphorus atom is close to phosphonium. An analogous structure of the intermediate complexes is proposed upon the catalysis of the imide-amide rearrangement by BF₃. The introduction of acyl groups such as phosphoryl, thiophosphoryl, and methanesulfonyl groups to the nitrogen atom of the triphenylphosphinimine alters the site of attachment of BF₃, which is found at the oxygen atoms of the P-O or SO₂ groups or to the sulfur atom of the P-S group.Translated from Izvestiya Akademii Nauk SSSR, Seriya Khimicheskaya, No. 3, pp. 713–718, March, 1991.The authors express their deep gratitude to M. G. Galakhov for taking and interpreting the¹⁹F NMR spectra.     

Ru–η6‐Arene Cations [{(Ph2PC6H4)2B(η6‐Ph)}RuX]+ (X=Cl,H) as Lewis Acids

The reactivity of [{(Ph₂PC₆H₄)₂B(η⁶‐Ph)}RuCl][B(C₆F₅)₄] ( 1 ) as a Lewis acid was investigated. Treatment of 1 with mono and multidentate phosphorus Lewis bases afforded the Lewis acid–base adducts with the ortho‐carbon atom of the coordinated arene ring. Similar reactivity was observed upon treatment with N‐heterocyclic carbenes; however, adduct formation occurred at both ortho‐ and para‐carbon atoms of the bound arene with the para‐position being favoured by increased steric demands. Interestingly treatment with isocyanides resulted in adduct formation with the B‐centre of the ligand framework. The hydride‐cation [{(Ph₂PC₆H₄)₂B(η⁶‐Ph)}RuH] [B(C₆F₅)₄] was prepared via reaction of 1 with silane. This species in the presence of a bulky phosphine behaves as a frustrated Lewis pair (FLP) to activate H₂ between the phosphorus centre and the ortho‐carbon atom of the η⁶‐arene ring.     

Enzymatic resolution of α-hydroxyphosphinates with two stereogenic centres and determination of absolute configuration of stereoisomers obtained

The use of quinine as a chiral solvating agent allows us to determine a tentative absolute configuration at the phosphorus atom of hydroxyphosphinates with two stereogenic centres (at the phosphorus and α-carbon atoms). Two ethyl butyryloxyalkane(P-phenyl)phosphinates were hydrolysed using various lipases. In all cases isomers possessing α-carbon atom with an (S)-configuration were hydrolysed preferentially. The absolute configuration of both chiral centres of obtained α-hydroxyphosphinates was determined by using (S)-(+)-MTPA-Cl and quinine. The mode of chiral discrimination of α-hydroxyphosphinates by quinine was studied by means of computational chemistry, which confirmed the experimental findings that the signals in ³¹P NMR spectra of compounds with an (R_P)-configuration are situated upfield when compared with the respective (S_P) isomers.     

Planar Chiral,Ferrocene‐Stabilized Silicon Cations

The preparation of a series of planar chiral, ferrocenyl‐substituted hydrosilanes as precursors of ferrocene‐stabilized silicon cations is described. These molecules also feature stereogenicity at the silicon atom. The generation and ²⁹Si NMR spectroscopic characterization of the corresponding silicon cations is reported, and problems arising from interactions of the electron‐deficient silicon atom and adjacent C(sp³)?H bonds or aromatic π donors are discussed. These issues are overcome by tethering another substituent at the silicon atom to the ferrocene backbone. The resulting annulation also imparts conformational rigidity and steric hindrance in such a way that the central chirality at the silicon atom is set with complete diastereocontrol. These chiral Lewis acid catalysts were then tested in difficult Diels–Alder reactions, but no enantioinduction was seen.     

Enantioselective reduction of α-substituted ketones mediated by the boronate ester TarB-NO2

A facile and mild reduction procedure is reported for the preparation of chiral secondary alcohols prepared from α-substituted ketones using sodium borohydride and the chiral boronate ester (l)-TarB-NO₂. Direct reduction of substituted ketones bearing Lewis basic heteroatoms generally provided secondary alcohols of only modest enantiomeric excess likely due to either competition between the target carbonyl and the functionalized sidechains at the Lewis acidic boron atom in TarB-NO₂ or the added steric bulk of the α-sidechain. As an alternative method, these substrates were synthesized using TarB-NO₂ via a two-step procedure involving the reduction of an α-halo ketone to a chiral terminal epoxide, followed by regioselective/regiospecific epoxide opening by various nucleophiles. This procedure provides access to a variety of functionalized secondary alcohols including β-hydroxy ethers, thioethers, nitriles, and amines with enantiomeric excesses of 94% and yields up to 98%.     

Ethers on Si(001): A Prime Example for the Common Ground between Surface Science and Molecular Organic Chemistry

By using computational chemistry it has been shown that the adsorption of ether molecules on Si(001) under ultrahigh vacuum conditions can be understood with classical concepts of organic chemistry. Detailed analysis of the two‐step reaction mechanism—1) formation of a dative bond between the ether oxygen atom and a Lewis acidic surface atom and 2) nucleophilic attack of a nearby Lewis basic surface atom—shows that it mirrors acid‐catalyzed ether cleavage in solution. The O−Si dative bond is the strongest of its kind, and the reactivity in step 2 defies the Bell–Evans–Polanyi principle. Electron rearrangement during C−O bond cleavage has been visualized with a newly developed method for analyzing bonding, which shows that the mechanism of nucleophilic substitutions on semiconductor surfaces is identical to molecular S_N2 reactions. Our findings illustrate how surface science and molecular chemistry can mutually benefit from each other and unexpected insight can be gained.     

Optically active (2-aminomethylferrocenyl) phosphines with the phosphorus chiral center

The reaction of an enantiomeric planar-chiral palladium derivative of dimethyl-aminomethylferrocene with PhMePLi in THF at room temperature afforded a 1.5∶1.0 mixture of diastereomeric aminophosphines containing the phosphorus asymmetrical center along with a chiral plane. The absolute configuration of the phosphorus atom was determined based on the X-ray diffraction data for the complex of the minor diastereomer with PdI₂. The presence of the (S)-chiral plane in the initial palladium compound favors the predominant formation of the product with the (S)-configuration of the phosphorus center.     

Chiral Lewis acid catalysis in a visible light-triggered cycloaddition/rearrangement cascade

Cascade (domino) reactions facilitate the formation of complex molecules from simple starting materials in a single operation. It was found that 1-naphthaldehyde derivatives can be converted to enantioenriched (82–96% ee) polycyclic benzoisochromenes via a cascade of ortho photocycloaddition and ensuing acid-catalysed rearrangement reactions. The cascade was initiated by irradiation with visible light (λ = 457 nm) and catalysed by a chiral AlBr₃-activated 1,3,2-oxazaborolidine (14 examples, 65–93% yield). The absolute configuration of the products was elucidated by single crystal X-ray crystallography. Mechanistic experiments suggest that the ortho photocycloaddition occurs on the triplet hypersurface and that the chiral catalyst induces in this step the observed enantioselectivity.

Chiral Lewis acid catalysis enables the formation of enantioenriched polycyclic benzoisochromenes 2 from simple 1-naphthaldehydes 1 in an efficient cascade process triggered by a visible light-initiated ortho photocycloaddition.     

STEREOSELECTIVE REACTIONS OF CHIRAL AMINES WITH RACEMIC CHLOROPHOSPHINES

Racemic chlorophosphines react stereoselectively with chiral l-phenylethylamines or amino acid esters to give diastereomerically enriched aminophosphines 3, which were isolated as diastereomerically pure crystalline borane complexes. Oxidation, thionation, the reaction with methyl iodide provide optically active derivatives of aminophosphines. (R,S)- and (S,S)-stereomers of phosphinic acid amides were separated by crystallization and a flash-chromatography. The stereochemical properties of phosphorus acid amides were investigated. The mechanism of asymmetric induction at the trivalent phosphorus atom was rationalized.     

An axially chiral, electron-deficient borane: synthesis, coordination chemistry, Lewis acidity, and reactivity

An axially chiral dihydroborepine with a binaphthyl backbone and a C(6)F(5) substituent at the boron atom was prepared by transmetalation from the corresponding tin precursor. This novel motif was structurally characterized by X-ray diffraction analysis as its THF and its PhCN Lewis acid/base complex. (1)H NMR measurements at variable temperatures of the former adduct revealed a remarkable dynamic behavior in solution. Several more Lewis pairs with oxygen, nitrogen, carbon, and phosphorus σ-donors were synthesized and analyzed by multinuclear NMR spectroscopy. The determination of the borane's Lewis acidity with the Gutmann-Beckett method attests its substantial Lewis acidity [85% with Et(3) PO as well as 74% with Ph(3) PO relative to the parent B(C(6)F(5))(3)]. Representative examples of Si-H bond activation (carbonyl reduction and dehydrogenative Si-O coupling) are included, demonstrating the chemical stability and the synthetic potential of the new chiral boron-based Lewis acid.     

Enantioselective radical-mediated allylation of α-iododihydrocoumarins using Lewis acids generated from chiral sulfonamides

Enantioseletive radical-mediated allylation using chiral Lewis acids generated from sulfonamides is described. Asymmetric allylation took place in 54% enantiomeric excess to form a chiral quaternary carbon center with R configuration. The present reaction proceeded equally well with a substoichiometric amount of a chiral Lewis acid as with a stoichiometric amount.     

C-phosphorylation of formaldehyde and crotonaldehydeN,N-dimethylhydrazones

The first representatives of hydrazones having trivalent phosphorus at the azomethine carbon atom or the carbon atom vinylogous to it were synthesized by reactions of formaldehyde and crotonaldehydeN,N-dimethylhydrazones with PBr₃ and diphenylchlorophosphine in the presence of organic bases. Some properties of the compounds synthesized were studied. Translated fromIzvestiya Akademii Nauk. Seriya Khimicheskaya, No. 9, pp. 1797–1801, September, 1998.     

Chiral Lewis acid catalyzed resolution of racemic enol ester epoxides. Conversion of both enantiomers of an enol ester epoxide to the same enantiomer of acyloxy ketone

This paper describes an efficient kinetic resolution of racemic enol ester epoxides via a chiral Lewis acid catalyzed rearrangement. Both enantiomerically enriched enol ester epoxides and alpha-acyloxy ketones can be obtained through this resolution. A positive nonlinear effect is observed in this process. By taking advantage of the mechanistic duality in acid-catalyzed enol ester epoxide rearrangement, we can completely convert a racemic enol ester epoxide into an enantiomerically enriched alpha-acyloxy ketone by treatment with a catalytic amount of a chiral Lewis acid followed by a catalytic amount of an achiral protic acid.     

PHOSPHORANES PAR FERMETURE TRANS ANNULAIRE IV. Quelques Exemples de Phosphoranes Bicycliques Chiraux

Abstract

Nous avons synthétisé sept phosphoranes bicycliques nouveaux 1–7 comportant un atome de phosphore pentacoordiné chiral. 5 et 6 possèdent en outre un atome de carbone chiral et 7 deux atomes de carbone chiraux. Une étude comparative des paramètres RMN du groupement P–H nous a permis de proposer une configuration de l'atome de phosphore de ces trois composés.

Seven new bicyclic phosphoranes 1–7 bearing a chiral pentaco-ordinated phosphorus atom are described. 5 and 6 possess a chiral carbon atom and 7 two chiral carbon atoms. A configuration of phosphorus atom of these three compounds is proposed based on a comparative study of the P–H NMR parameters.