Zur Umsetzung des Zweikomponentensystems Trialkylphosphit/Tetrachlorkohlenstoff mit Nucleophilen 3. Die Reaktion in Gegenwart von Ammoniumsalzen

Reaction of the Two-component System Trialkylphosphite/Carbon Tetrachloride with Nucleophiles. 3. Reaction in Presence of Trialkylammoniumsalts Alkali pseudohalogenides (KSCN, NaN₃, KCN) react with the two component system trialkyl phosphite/carbon tetrachloride in presence of trialkylammonium halogenides. Isothiocyanates of dialkylphosphorus acid, N-alkyl phosphoric acid diester amides, N-dialkoxyphosphoryl trialkoxy phosphazenes and tricyano phosphane oxide respectively, are obtained. In the system (RO)₃P/CCl₄/R₃NHI the dialkoxy phosphoryl chloride is formed.     

Zur Umsetzung des Zweikomponentensystems Triethylphosphit/Tetrachlorkohlenstoff mit wasserstoffhaltigen Nucleophilen 1. Die Reaktion mit Säureamiden

Reaction of the Two-component System Triethylphosphite/Carbon Tetrachloride with Nucleophiles Containing Hydrogen. 1. Reaction with Acyl Amides Acyl amides react with the two-component system triethylphosphite/carbon tetrachloride yielding N-acyl phosphazenes, (EtO)₃P?N? Ac. In this way (EtO)₃P?N? P(O)(OEt)₂, (EtO)₃P?N? CN, (EtO)₃P?N? C(O)Ph, and (EtO)₃P?N? SO₂Ph were prepared. Ethyl esters of phosphoric acid and trichloromethane phosphonic acid were obtained as by-products.     

Darstellung und oxidative Derivatisierung von Dialkylthiophosphiten

Preparation and Oxidative Derivatisation of Phosphonothionic Esters The kind of the amine used influences decisively course and rate of the reaction of trialkyl phosphites, (RO)₃P (R = Me, Et, Ph) with H₂S in the presence of different amines (Et₃N, Et₂NH, Et₂NPh, pyridine). Phosphonothionic esters, (RO)₂P(S)H (R = Me, Et, Bu), are obtained in over 80% yield by using pyridine as base and an alkali alcoholate as catalyst. The oxidative derivatisation of phosphonothionic esters by means of CCI₄ and protic (4-nitrophenol, 2,4,5-trichlorophenol, ammonia, piperidine, phenylhydrazine) or anionic nucleophiles (F^?, NCS^?, NCO^?, CN^?, N₃^?) (Atherton-Todd reaction) yields thiophosphoric acid derivatives (RO)₂P(S)Nuc (R = Me, Et, Bu: Nuc = 4-nitrophenoxy, PhNHNH; R = Me, Et: Nuc = 2,4,5-trichlorophenoxy, F, NCS, N₃; R = Me: NH₂, C₅H₁₀N; R = Et: Nuc = CI, CN) and in some cases the dealkylated products (RO)P(Nuc)SO^? (R = Me; Nuc = CI, F, NCS, CN). The phosphazenes (EtO)₂P(S)? N = PPh₃ and (MeO)₂P(S)? N ? P(OEt)₃, up to now unknown in literature, were obtained by treating thiophosphoryl azides with PPh₃ or P(OEt)₃, resp.     

Synthese bindungsisomerer Alkoxy(aroxy)phosphoryl-tricyanmethanide,ein Beitrag zur Pseudohalogenid-Ambivalenz

Synthesis of Isomeric Alkoxy(aroxy)phosphoryl-tricyanmethanides, a Contribution to the Ambivalency of Pseudohalides The synthesis of a series of alkoxy(aroxy)phosphoryltricyanmethanides of the isomeric types (RO)₂P(O)NCC(CN)₂ and (RO)₂P(O)C(CN)₃ is reported. Synthetic routes as well as IR- and ³¹P-NMR spectra are indicating close relations of the new compounds to homologeous phosphoryl-pseudohalides (RO)₂P(O)NCY and (RO)₂P(O)YCN (Y: NCN, O). Thus the presented results are clearly emphasizing the pseudochalcogen-character of the C(CN)₂-group.     

Synthesis of Poly(dialkylphosphazenes) from N-Silylphosphinimines

Many N-silylphosphinimines Me₃SiN?P(X) RR′ undergo facile thermal decomposition with elimination of substituted silanes Me₃SiX and formation of cyclic or polymeric phosphazenes (RR′PN). The process which is a new, general synthesis of phosphazenes has been used to prepare poly(dimethylphosphazene), (Me₂PN), in nearly quantitative yield from Me₃SiN?P(OCH₂CF₃)Me₂. Convenient synthetic routes to the necessary silicon-nitrogen-phosphorus precursors are described and the results of their decomposition reactions are reported.     

Synthese von N-Di(alk-, ar-)oxyphosphoryl-tri(alk-, ar-)-oxyphosphazenen, (RO)2P(O)?NP(OR)3, durch P?N-Bindungsknüpfung

Synthesis of N-Di(alk-, ar-)oxyphosphoryl-tri(alk-, ar-)oxyphosphazenes, (RO)₂P(O)? N?P(OR)₃, by P? N-Bond Formation The title compounds can be prepared from di- and triesters of phosphorous acid, sodium azide, and carbon tetrachloride in a single step procedure and in high yields. Due to the combination of the Atherton-Todd and the Staudinger reaction toxic phosphoric acid ester azides are formed only in situ and their concentration is kept very small. As by-products trichloromethane phosphonic acid esters, (RO)₂P(O)CCl₃, esters of phosphoric acid and condensed phosphoric acids as well as N-alkylimidodiphosphoric acid esters, [(RO)₂P(O)]₂NR, are formed. Their formation can be avoided or reduced by choosing suitable reaction conditions. The mechanism of the reaction is discussed.     

Zur Umsetzung des Zweikomponentensystems Trialkylphosphit/ Tetrachlorkohlenstoff mit wasserstoffhaltigen Nucleophilen 2. Die Reaktion mit Ammoniak und Aminen

Reaction of the Two-component System Trialkylphosphite/Carbon Tetrachloride with Nucleophiles Containing Hydrogen. 2. Reaction with Ammonia and Amines Ammonia and primary amines react with the two-component system trialkylphosphite/carbon tetrachloride yielding diester-amides of phosphoric acid, (RO)₂P(O)NHR′. If an excess of amine is used compounds of the type ROP(O)(NHR′)₂ and OP(NHR′)₃ are formed too. By the reaction of (RO)₃P/CCl₄ in presence of secondary and tertiary amines the first reaction product is (RO)₂P(O)CCl₃ which yields with the amine [NRR′R″R″′]⁺[Cl₃CP(OR)O₂]^?; (R = Et, Bu).     

Pathways in the Nucleophilic Substitution Reactions of Halogenocyclophosphazenes and Subtle Aspects of the Mechanism of Formation of Bicyclic Phosphazenes

Abstract

Both associative [S_N2(P)] and dissociative [S_N1(P) and E₁CB] mechanisms have been established for the amination reactions of haloenocyclophosphazenes from synthetic and kinetic studies. Several intricate details concerning the formation of bicyclic phosphazenes have been unravelled.     

A Cyclic and Polymeric Phosphazene as Solid State Template for the Formation of RuO<Subscript>2</Subscript> Nanoparticles

Pyrolysis of the organometallic polymer: {{[N=P(R₁)]_0.8[N=P(OC₆H₄CH₂CN[Ru])₂]_0.15[N=P((OC₆H₅)(OC₆H₄CH₂CN[Ru]]_0.05}{Cl}_0.31} _n , [Ru]=CpRu(PPh₃)₂, R₁ = O₂C₁₂H₈ (1) as well of the cyclic specie {N₃P₃ (OC₆H₅)₅(OC₆H₄CH₂CN[Ru])}{PF₆} (2) under a flow of air at 800°C affords nanostructured RuO₂. Nanoparticles near to 10 nm were observed. The differences in the use of cyclic or polymeric phosphazenes, as solid state template, influence strongly the morphology and slightly the composition of the pyrolytic product. Temperature variable (SQUID) measurements in the range of 5–300 K of the material obtained from the polymer, indicate an antiferromagnetic interaction between the Ru atoms, although lower than that found for the crystalline ruthenium oxide, probably due to some amorphous product present in the pyrolytic material. The possible formation mechanism is discussed and the differences in using the cyclic or the polymeric compound as precursor is analyzed in terms of the relative content of Ru to P, N. A general formation method of nanostructured metal oxides is proposed.     

NEW CYCLIC AND POLYMERIC PHOSPHAZENES DERIVED FROM N-SILYLPHOSPHORANIMINES

Silicon-nitrogen-phosphorus compounds of the type Me ₃ SiN═PR(R′)X(X= Cl, Br, OCH₂CF ₃ , OPh), known as N-silylphosphoranimines,are useful precursors to both cyclic and polymeric phosphazenes.Depending on the leaving group (X), thermolysis reactions afford either cyclic trimers, [N═PR(R′)] ₃ (when X = Cl, Br), or linear polymers,[N═PR(R′)]_n (when X = OCH ₂ CF ₃ or OPh). Treatment of the P-trifluoroethoxy and P-phenoxy derivatives, Me ₃ SiN═PR(R′)X (X = OCH ₂ CF ₃ , OPh), with alcohols at lower temperature usually results in the formation of cyclic phosphazene trimers via silyl ether elimination. Recently, we have applied these synthetic methods to the preparation of some new phosphazene systems including a series of 4-aryl-functionalized trimers and polymers and a variety of non-geminal, mixed-substituent cyclic trimers. Representative examples of the synthesis, structural characterization, and reactivity of these new phosphazenes and their Si─N─P precursors are reported here.     

Substitutions- und Oxydationsreaktionen des N-Dichlorphosphanyl-triphenylphosphazens,Ph3PN?PCl2

Replacement and Oxidation Reactions of N-Dichlorophosphanyl Triphenylphosphazene, Ph₃P?N? PCl₂ The title compound ( 1 ) reacts with MeOH, EtOH, PhOH, EtSH, and water forming N-phosphanyl or N-phosphinoyl phosphazenes, resp., Ph₃P?N? PX₂ (X ? OPh( 8 ), SEt( 9 )) or Ph₃P?N? PH(O)X (X ? Cl( 3 ), OH( 4 ), OMe( 5 ), OEt( 7 )). The reaction of 1 with P(NEt₂)₃ yields Ph₃P?N? P(NEt₂)₂ ( 10 ). Ph₃P?N? PF₂( 11 ) and Ph₃P?N? PH(O)F ( 12 ) are obtained by chlorine-fluorine exchange. The N-phosphanyl compounds 1 , 8 , 9 and 11 are oxidized by NO₂ yielding the corresponding N-phosphoryl derivatives, Ph₃P?N? P(O)X₂ (X ? Cl( 2 ), OPh( 13 ), SEt ( 14 ), F( 15 )). The thiophosphoryl compounds, (Ph₃P?N? P(S)X₂ (X ? Cl( 16 ), OPh( 17 ), F( 18 )) are obtained by oxidizing 1 , 8 , and 11 with sulfur.     

The Gas-Chromatographic Behaviour of the Phosphoric Acid n-Alkyl Esters on Silicon Stationary Phases. Reactions on Columns

Abstract

Instability of the trialkylphosphates (RO)₃P(O), with R ? C₂H₁₁ - C₈H₁₇ has been observed when pairs of these esters were analysed on gas-chromatographic columns with silicone stationary phases, e.g., OV-17. New peaks were identified between those corresponding to the initial esters analysed separately. The Kovats retention indices were calculated for these peaks, with n-alkanes, as standards and phosphorus indices with tri-n-alkyl-phosphates as standards. The relationships between the retention indices and the number of the total carbon atoms in the molecules of the alkyl-phosphates was represented for the identification of the new peaks. The new peaks were identified as mixed phosphates with general structure (RO)z(RO)P(O), where R and R are alkyl radicals C₅H₁₁-C₆H₁₇. These phosphates are the results of interchange of alkoxy groups from the esters in the conditions of high temperature (240°C) of the chromatographic colums. The retention data of the esters examined are shown in the table.     

Palladium(II) Chloride Interaction with Chelating BIS(Phosphine Sulfides). Effect of the Ligand Structure on the Complex Geometry

Abstract

Interaction of PdCl₂ in chloroform with bis(phosphine sulfides) Ph₂P(S)?X?P(S)Ph₂ (X?CH₂, C(CH₃)₂, CH₂CH₂, NH, S, and SCH₂S) has been studied. Mechanism of the reaction has been found to vary dramatically with the identity of X. The structures of the resultant complexes were evaluated by UV and IR spectroscopy. Crystal structures were were determined by X-ray diffraction for two of the compounds (A: [Ph₂P(S)?(CH₂)₂?P(S)Ph₂]PdCl₂ · CH₃CN, P2₁/n, Z = 4, a = 10.104(2), b = 20.939(4), c = 14.034(3) Å, γ = 102.54(2)· B: [Ph₂P(S)?N?P(S)Ph₂]₂Pd · 2CHCl₃, Pl, Z = 1, a = 9.539(1), b = 12.333(3), c = 12.866 Å, α = 111.83(2)°, β = 96.70(3)° γ = 99.84(3)°).     

Interaction of Dialkyl (α-Carbomethoxy-β,β,β-Trifluoro-Ethyl) and Dialkyl-S-Carboethoxychloromethylthiol Phosphates with Mammalian Esterases. Role of Esterases in Toxicity Mechanisms

Abstract

The interaction of insecticides (RO)₂P (0)OCH (CF₃) COOCK₃ (I) and (RO)₂P(0)SCH(X)COOC₂H₅ (X=Cl(II), Br(III); R=Me, Et, Pr, i-Pr, Bu, i-Bu, Am, Hex) with acetylcnolinesterase (ACnE), butyrylcholinesterase (BChE) and carboxylesterase (CE) was studied in connection with their role in organo-phosphate toxicity mechsnisms. Toxicity of I–III to mice was determined. I–III were not hydrolysed by CE and irreversibly inhibited all the enzymes, II, IIi had a greater inhibitory potency compared to I: lgk^II _AChE = 2–4 (I), 6 (II, III); lgk^II _BChE = 3–6 (I), 5–8 (II, III); lgk^II _CE = 3–7 (I), more than 8 (II, III). With multiple regression analysis the dependence of antienzymatic activity on hydrophobicity and steric properties of alkyl substituents was investigated. The contribution of the hydrophobic interactions to dChE and CE (enzymes-“sites of loss”) inhibition was the same and more significant than that to AChE (target enzyme) inhibition. Steric effects are more important in AChE inhibition. The dependences lg(I/LD₅₀) = f(ΓΠ) for I–III were in great extent determined by binding with nonspecific esterases that rises with increasing hydrophobicity. These results indicate that nonspecific esterases CE and BChE play a buffer role in toxic action of I and especially II and III.     

Reactions of metallocenes during intercalation into the layered TiSe2 lattice

The intercalation of metallocenes (Cp₂Co, Cp₂Fe, and Cp₂Ni, where Cp is η⁵-C₅H₅) from the gas phase into the TiSe₂ lattice and of cobaltocene from solutions in acetonitrile, carbon tetrachloride, and chloroform into TiSe₂ was studied. The insertion of metallocenes from the gas phase into the TiSe₂ lattice gives rise to the TiSe₂(Cp₂M)_0.3 compounds (M = Co or Fe) having the same stoichiometry. The reactions with the use of acetonitrile as the solvent for metallocenes, which facilitates the insertion, afford not only the intercalation complex but also the reaction product of metallocene and acetonitrile, viz., (η ⁵-C₅H₅)Co(η⁴-C₅H₅CH₂CN) (1). In the reactions of cobaltocene with chloroform or carbon tetrachloride in the presence of titanium diselenide, only the addition product, viz., (η ⁵-C₅H₅)Co(η₄-C₅H₅CCl₃) (2), was isolated. The structures of complexes 1 and 2 were studied by X-ray diffraction. Published in Russian in Izvestiya Akademii Nauk. Seriya Khimicheskaya, No. 5, pp. 876–880, May, 2007.     

Bis(diphenylphosphino)Alkane / Co(II)/Tetrahydroborate and Cyanotrihydroborate Reactions: Formation of Unusual Bis(diphenylphosphino)methane Complexes and the Influence of Carbon Monoxide

Abstract

Reactions between Co(II), bis(diphenylphosphino)methane (dppm) and either NaBH₄ or NaBH₃CN have been studied. They follow pathways which are in marked contrast to those followed by Ph₂P(CH₂)nPPh₂ (n=2?6) in the presence of NaBH₄ in which the final product is normally CoH(phosphine)₂ although binuclear BH₄-bridged complexes may sometimes be obtained. The products obtained with dppm are Co₂X₃(dppm)₂ (X=Cl,Br) (I), CoCl(dppm)₃ (II), {CoHX(dppm)₂}Y (X=Cl, Br, I, BH₃CN; Y=Cl,BH₃CN,BPh₄,Clo₄) (III), and Co₂H₂(dppm)₃ (IV). While a binuclear A-frame structure can be proposed for the Co(I)-Co(II) species (I), crystal twinning has so far prevented an X-ray determination. However, X-ray studies on (II) and (IV) have shown that (II) contains tetrahedral Co(I) to which one chloro and three monodentate dppm ligands are attracted while (IV) is a binuclear species containing bridging dppm ligands and two terminal hydrides. The compounds (III) are octahedral Co(III) complexes. Possible mechanisms for the formation of these in strongly reducing environments will be discussed.     

The Reactions of Hexachlorocyclotriphosphazatriene with Ligands Including Mercapto Groups

In this work, the reactions of hexachlorocyclotriphosphazatriene (trimer), N ₃ P ₃ Cl ₆ 1, with 2-mercapto-1-methylimidazole (methimazole) 2, 2-mercaptopyrimidine 3, and 2-mercaptopyridine 4 were discussed. Mono- (5) and pentasubstituted (6) phosphazenes were obtained from the reaction of 1 with 2-mercapto-1-methylimidazole. Both mono- (7) and disubstituted geminal (8) phosphazenes were obtained from the reaction of 1 with 2-mercaptopyrimidine. But phoshazene or any phosphorus compound could not be isolated from the reaction of 1 with 2-mercaptopyridine.     

Synthesis of Boron–Nitrogen–Phosphorus Compounds from N-Silylphosphoranimines

Two modes of reactivity of N-silylphosphoranimines have been utilized to prepare the title compounds containing either B–N=P or Si–N=P–N–B linkages. First, silicon-nitrogen bond cleavage reactions of the N-silylphosphoranimines, Me₃SiN=PMe(R)OCH₂CF₃ (1: R=Me, 2: R=Ph), with various chloroboranes gave the new N-borylphosphoranimines, Ph(Me₂N)B–N=PMe₂OCH₂CF₃ (2) and [(Me₃Si)₂N](Cl)B–N=PMe₂OCH₂CF₃ (10). In other cases, however, the expected B–N=P products were unstable and cyclic phosphazenes [Me(R)P=N]_3,4 were obtained. Second, deprotonation-substitution reactions of the aminophosphoranimines, Me₃SiN=P(R)Me–N(R)H, were used to prepare a series of novel (borylamino)-phosphoranimines, Me₃SiN=P(R)(Me)–N(R)–B(NMe₂)₂ (18: R=Me, R=t-Bu; 19: R=R=Me; 20: R=Ph, R=t-Bu; 21: R=Ph, R=Me) and Me₃SiN=PMe₂–N(t-Bu)–B(Ph)X (22: X=NMe₂, 23: X=OCH₂CF₃). All of the new boron–nitrogen–phosphorus products were fully characterized by multinuclear NMR (¹H, ¹³C, and ³¹P) spectroscopy and elemental analysis.     

Fluoridolyse von N-Phosphorylphosphazenen

Fluoridolysis of N-Phosphoryl Phosphazenes In the reaction of the N-phosphoryl phosphazenes X₃P?N? P(Y)X₂ (X = Cl, PhO, Et₂N, CF₃CH₂O, PrS, Ph; Y = O, S) ( 1 – 18 ) with Et₃N · nHF (n ≈? 3 or 0.6) fluoro derivatives of N-phosphoryl phosphazenes (see table 2) as well as N-phosphorylated imiddotetrafluorophosphates, [F₄P?N? P(Y)Cl₂]^? (Y = O, S), and imidopentafluorophosphates, [F₅P? N? P(Y)X₂]^2? or [F₅P? NH? P(O)X₂]^? (see table 3), are formed. t-BuNHPCl₂?N? POCl₂ reacts in acetonitrile with Et₃N or i-Pr₂EtN to form a product, representing probably the diazadiphosphetine ( 5 b ).     

The Interaction of Thioethynyl Esters of Thiophosphoric Acids with Cytochrom P 450

Abstract

We have shown that thioesters of phosphoric acids of general formula (RO)₂P(X)C[tbnd]CR¹, were X=O or S, containing an acetylenic bond in α-position of the S-ester group has unugually high destructive effect on some isoforms of cytochrome P 450 of arthropods and mammals. These isoforms probably, participate in the process of inactivation of the acetylenic thioesters. We assume that this process may be thought as being a rupture of rhe P-S bond, which leads to the formation of killer particles - alkylthioketenes.