Über Trichlorphosphazo-Verbindungen aus Nitrilen. I

The compound [HCCl=C(NPCl₃)(PCl₃)[PCl₆], VI, is formed in the reaction between acetonitrile and PCl₅. Reaction of H₂S with VI results in the formation of the chloride and by further reactions of this chloride with BCl₃ and SbCl₅ the tetrachloroborate and hexachloroantimonate salts respectively, are obtained. Chloroacetonitrile can be made to react with PCl₅ to give HCCl?C(NPCl₃)Cl, II, by use of suitable conditions. There is no indication that mixtures of cis/trans isomers of VI or II exist as has been previously postulated. The ¹H and ³¹P NMR spectra of the above-mentioned compounds and numerous further products from the reactions of CH₃CN, ClCH₂CN and Cl₂CHCN with PCl₅ are discussed in detail. II occurs in a cisoid and a transoid conformation.     

Perfluoralkylierte Säuren des Phosphors. II. Zur Kenntnis der Trifluormethyl-benzol-phosphinsäure

Perfluoroalkylated Acids of Phosphorus. II. On Trifluoromethyl Benzene Phosphinic Acid Bis-(trifluoromethyl-benzene) phosphinic acid anhydride 1 , easily formed by CF₃COOH and C₆H₅PCl₂, yields on reaction with aqueous Na₂CO₃ solution the sodium salt of trifluoromethyl benzene phosphinic acid 2 . The acid itself is isolated by ion exchange as a hygroscopic and highly acidic substance.     

Über Trichlorphosphazo-Verbindungen aus Nitrilen. III. Die Reaktion zwischen Acrylnitril und PCl3

On Trichlorophosphazo Compounds from Nitriles. III. The Reaction between Acrylonitrile and PCl₃. The reaction of PCl₃ with acrylonitrile at higher temperatures gives CH₂Cl? CCl₂? CCl₂? N? PCl₃ ( II ). On pyrolysis of (II), CH₂Cl? CCl₂? CN (IV) is form- ed. Treatment of (II) with SO, results in CHzCL? CCl₂? CCl?N-P(0)Cl₂ ( III ). At lower temperatures and/or in the presence of PCl₃, acrylonitrile reacts with PCl₃ to give the cis/ trans isomers VIa and VIb .     

Zur Kenntnis der Chemie der Silazane. IV. Über ein Sulfurylphosphazo-silazan

Trichlorophosphazo-sulphurylchloride. Cl₃P?N? SO₂Cl, reacts with heptamethyldisilazane to yield the Si? N? P compound (I) formulated in ?Inhaltsübersicht”?. (I) reacts with PCl₅ or C₆H₅? PCl₄ forming the known 2,2,2,4,4,4-hexachloro-1,3-di-methylcyclo-diphosphazane(II), accompanied by the compound Cl₃P?N? SO₂Cl and C₆H₅? PCl₂?N? SO₂Cl, respectively, which were detected by means of ³¹P-NMR spectroscopy.     

Über Phosphorstickstoffverbindungen,XXXII. Über Vier- und fünfgliedrige Heterocyclen mit Phosphor,Stickstoff und Kohlenstoff im Ring

On reacting of oxamide with PCl₅ the syntheses of the new N-, C- and pentavalent phosphorus containing heterocycles I and II (see “Inhaltsübersicht”), built up from interconnected four- and fivemembered ring systems, have been achieved. Reaction of N, N′- dimethyloxamide with PCl₃ yields the compound III which may be chlorinated to IV. An intermolecular reaction between the PCl₃- and carbonyl groups of IV gives V. The fivemembered ring systems III and V may each be linked together via N? CH₃ bridges, i. e. via P? N(CH₃)? P and P(O)? N(CH₃)? P(O) units, respectively. N, N′- dimethyloxamide reacts with PCl₅ to form a mixture of fivemembered heterocycles containing trivalent phosphorus (as a PCl group) and chlorinated carbon.     

Über sechsgliedrige Heterocyclen mit Phosphor-, Stickstoff- und Schwefelatomen im Ring

Cyclic sulphurylphosphazochloride (I: formula see ?Inhaltsübersicht”?) reacts with ammonia or methylamine forming the. tetramide(II) and (III), respectively, and with aniline or dimethylamine forming the diamide (IV) resp. (V). The synthesis of the diphenyl derivative (VI) is achieved starting from C₆H₅? PCl₄. (II) gives with PCl₅ the ionic compound (VII).     

Über Phosphorstickstoff-Verbindungen XXVIII. Über Reaktionen von Cyanamid,Dicyanimid und Dicyandiamid mit PCl5

Interaction between cyanamide and PCl₅ in the mole ratio 1:3 yields the phosphazenium salt [Cl₃P?N? C(Cl)?N? PCl₃] [PCl₆]. The reaction of sodium dicyanimide and PCl₅ gives 1. 1. 3. 5-tetrachloro-1-phospha-2. 4. 6-triazine (compound B in ?Inhaltsübersicht”?). Dicyandiamide and PCl₅ (1:2) give compound C and, at milder conditions the salt-like phosphatriazine D. Solvolysis of C with formic acid or of D with sulphur dioxide yields E.     

Darstellung,Kristall- und Molekülstruktur von Triphenylphosphinoxidhydrochlorid (C6H5)3PO · HCl

On Phosphazo Compounds from Nitriles. IV. The Reaction of Tri, Di, and Monochloroacetonitrile with [Cl₃P?N? PCl₃]Cl. Improved Preparation of [Cl₃P?N? PCl₃]Cl Trichloroacetonitrile reacts with P₂NCl₇ to give Cl₃C? CCl₂? N?PCl₂? N?PCl₃ I , dichloroacetonitrile to give Cl₂C?CCl? N?PCl₂? N?PCl₃ II , and chloroacetonitrile to give the ring compound III . Preparation, n.m.r. and mass spectra of the new compounds are described. The mechanism of formation is discussed. An improved procedure for the preparation of P₂NCl₇ is given.     

Über die Reaktion von Phosphorpentachlorid mit den BF3-Addukten primärer Amine

Reaction of CH₃NH₂ · BF₃ and PCl₅ yields CH₃N(PCl₃)(BCl₃), (I), the behaviour of which to PCl₅, pyridine and H₂S is described. By using smaller amounts of PCl₅, CH₃N(PCl₃)(BCl₂F) (VI) is obtained. C₆H₅NH₂ · BF₃ reacts with PCl₅ to give C₆H₅N(PCl₃)(BCl₃) (IX). Physical data, especially the NMR spectra of the new compounds, are given and discussed.     

Zur präparativen Bildung des Tri-tert.-butyl-nonaphosphans(3); P9(CMe3)3

Formation of Tri-tert.-butyl-nonaphosphane (3); P₉(CMe₃)₃ P₉(CMe₃)₃ 1 is formed by the reaction of “Na₃P/K₃P” with (Me₃C)PCl₂ [maximum yield 20% with regard to (Me₃C)PCl₂]. The molar ratio of the reactants used on this synthesis is Na/K:P₄:(Me₃C)PCl₂ is 4:1:2. The method of preparation is described.     

Über die Umsetzung von Adipinsäurediamid mit Phosphorpentachlorid

Reaction of Adipic Acid Diamide with Phosphorus Pentachloride The reaction of adipamide (I) with phosphorus pentachloride in a solvent leads to (Cl₃P?NCCl₂CCl₂CH₂)₂ (II). The stages of the reaction are: 1. chlorination of the keto and methylen groups 2. formation of the ? N?PCl₃ group. This result is a supplement of the existing conception about the course of the reaction of carboxylic acid amides with phosphorus pentachloride. The reaction of (I) with PCl₅ without any solvent has been reproduced and the course of reaction has also been investigated. This reaction gives mainly NC(CH₂)₄CN. The resulting product of a careful hydrolysis of (II) is (Cl₂OPN?CClCl₂CH₂)₂. A total hydrolysis gives back (I).     

Diaminodiphosphen- und aminophosphiniden-komplexe

2,2′,6,6′-Tetramethylpiperidylphosphorousdichloride, (pip)PCl₂, reacts with Na₂-M₂(CO)₁₀ (M = Cr, Mo, W) to give phosphinidene and diphosphene complexes. The diphosphene compounds [(pip)P=P(pip)]M(CO)₅ (Ia to Ic) are obtained as stable products for all three metals. The phosphinidene compounds (pip)[M(CO)₅]₂ are only obtained for M = Cr(IIa) and M = W (IIb). X-ray analyses reveal that the NR₂ substituents in I as well as in II are oriented in such a way relative to the phosphorus centered π-systems that they cannot participate in π-conjugation. This bonding situation is analyzed by EHT methods.     

Über Chalkogenolate. 166. Umsetzungen von Hydrazin mit Kohlenstoffdisulfid 5. Versuche zur Darstellung von Estern der 1,2-Hydrazin-bis(dithiocarbonsäuren) [1]

On Chalcogenolates. 166. Reactions of Hydrazine with Carbon Disulfide. 5. Attempts to Prepare Esters of 1,2-Hydrazine-bis(dithiocarboxylic Acids) Possible reactions to synthesize esters of 1,2-hydrazine-bis(dithiocarboxylic acids) are described:

• 1 The reaction of K₂[S₂C? NH? NH? CS₂] with H₃CI preponderantly forms 2,5-dimethylthio-1,3,4-thiadiazole Ia and a small quantity of bis(methylthio)-ketazine II (formula see ?Inhaltsübersicht”?).
• 2 Hydrazine reacts with Cl? CS? SC₂H₅ to give exclusively compound Ib
• 3 The reaction between K₂[S₂C=N? NH? CS? SCH₃] and H₃CI yields 94% compound Ia and 6% compound II
• 4 K₂[S₂C=N? NH? CS? SCH₃] reacts with C₆H₅? CH₂Br to form a mixture containing 25% dibenzyl sulfide, 15% 2,5-dibenzylthio-1,3,4-thiadiazole I e, and 60% 2-methylthio-5-benzylthio-1,3,4-thiadiazole I d

The compounds Ia , Id and II have been characterized by means of diverse spectroscopic methods. The mechanism of the formation of compounds I has been discussed.     

Reactions of some 2-oxo-1,3,2-oxathiaphospholanes and 2-oxo-1,3,2-phosphorinanes with phosphorus pentachloride

2-Phenoxy- and 2-dialkylamino-2-oxa-1,3,2-oxathiaphospholanes react with PCl₅ with ring opening and formation of the corresponding acid chlorides of thiophosphoric acid. Under analogous conditions, 2-phenoxy-2-oxo-1,3,2-oxathiaphosphorinanes do not react with PCl₅, while acid chlorides of thiophosphoric acid are formed in low yield along with other products in the reaction of 2-dialkylamino-2-oxo-1,3,2-oxthiaphosphorinanes with PCl₅.A. E. Arbuzov Institute of Organic and Physical Chemistry, Kazan Science Center, Russian Academy of Sciences, 420083 Kazan. Translated fromIzvestiya Akademii Nauk, Seriya Khimicheskaya, No. 11, pp. 2676–2678, November, 1992.     

Reactions of alkenes with phosphorus pentachloride and trichlorosilane

Conclusions Alkenyldichlorophosphines are formed in high yields when alkenes are phosphorylated by treatment with PCl₅ in the presence of hydrosilanes under conditions that promote the formation of trimolecular complexes of alkene, PCl₅, and hydrosilane.Translated from Izvestiya Akademii Nauk SSSR, Seriya Khimicheskaya, No.1, pp.207–209, January, 1976.     

Gasphasen-Reaktionen. 92. Thermische HCl-Abspaltung aus Alkyldichlorphosphanen (H3C/H)3C?PCl2 zu Phosphaalkenen (H3C/H)2CPCl und Phosphaalkinen (H3C/H)C≡P

Gasphase Reactions. 92 Thermal Elimination of HCl from Alkyldichlorophosphanes (H₃C/H)₃C? PCl₂ to Phosphaalkenes (H₃C/H)₂C?PCl and Phosphaalkines (H₃C/H)C≡P The alkyldichlorophosphanes H₃C? PCl₂, ClH₂? PCl₂, (H₃C)H₂C? PCl₂ and (H₃C)₂HC? PCl₂ split off HCl on heating in a gasflow under reduced pressure. PE spectroscopic gas analysis proves that under these conditions the short-lived phosphaalkenes H₂C?PCl, (H₃C)H₂C?PCl and – catalyzed by [MgCl₂? MgO/SiO₂]_∞ – (H₃C)₂C?PCl as well as the phosphaalkines HC≡P and (H₃C)C≡P are formed, all of which can be isolated by low temperature condensation. Based on the PES ionization patterns recorded and on the MNDO calculations for their assignment, the π_CP multiple bonds are discussed. The presumable pathway of the HCl elimination is rationalized for (H₃C)H₂C? PCl₂ by an approximate MNDO energy hypersurface.     

Synthesis of chloropolyfluoroarenes from polyfluoroarenethiols and PCl<Subscript>5</Subscript>

Replacement of the thiol group in polyfluoroarenethiols with chlorine was performed by treating with PCl₅ as chlorinating agent. By heating in ampules at 200–220°C polyfluoro- and polyfluorochloroarenethiols with PCl₅ mono- and dichloropolyfluoroarenes and also 1,2,4-trifluorotrichlorobenzene were synthesized. Dichloropolyfluoroarenes contain chlorine atoms in ortho- and para-positions.     

Über die Reaktion von Phosphorpentachlorid mit den BF3-Addukten sekundärer und tertiärer Amine

Reaction of F₃B · NH(CH₃)₂ with PCl₅ yields [(CH₃)₂NPCl₃][BCl₄] (I), which can also be obtained by reaction of [(CH₃)₂NBCl₂]₂ with PCl₅. In BF₃ · N(CH₃)₃ the fluorine atoms are exchanged with chlorine atoms, by PCl₅, ³¹P, ¹⁹F, and ¹¹B-NMR spectra of the reactions products are described and discussed.     

Methyl-Dichlorophosphate von Zinn und Blei

Methyl Dichlorophosphates of Tin and Lead The compounds (CH₃)₃M(O₂PCl₂) (I), (M = Sn, Pb) and (CH₃)₂Sn(O₂PCl₂)₂ (II), formed by the reaction of the corresponding methyltin and methylleadchlorides with P₂O₃Cl₄ are described. The IR and Mössbauer spectra suggest that the tin compounds are polymerized through O? P? O bridges, whereby (I) and (II) contain metal atoms with coordination numbers five (D_3h) and six (D_4h), respectively.     

Synthese linearer und verzweigter Phosphazene aus N-silylierten Phosphorylamiden

Synthesis of Lineary and Branched Phosphazenes from N-silylated Phosphoryl Amides The use of N-silylated phosphoryl amides in the reaction with PCl₅ favours the KIRSANOV reaction and reduces undesirable substitution reactions. However, silylated monoamides, X₂P(O)NHSiMe₃ (X = OEt, NEt₂), do not give the expected trichlorophosphazenes but the isomeric N-dichlorophosphoryl phosphazenes, Cl₂P(O)? N?PClX₂, which are also formed in the reaction of (EtO)₂P(O)NCl₂ with PCl₅. As the first phosphoryl-P, P-bis(trichlorophosphazene) (EtO)P(O)(N?PCl₃)₂ could be obtained in the reaction of PCl₅ with the silylated diamide (EtO)P(O)(NHSiMe₃)₂. Tris reactivity of silylated amides to P? Cl compounds decreases in the row PCl₅ > POCl₃ > CIP(O)(OEt)₂ > ClP(O)(NEt₂)₂. In the reaction with phosphoryl chlorides the preferred formation of compounds with P? NH? P bridges could not be observed.