Umsetzung von 2-Azidoalkoholen mit Trialkylphosphiten Bildung von Aziridinen und Amidophosphorsäureesten via Imidophosphorsäureester und 1,3,2λ5-Oxazaphospholidine

Reaction of 2-Azidoalcohols with Trialkylphosphites. Formation of Aziridines and Amidophosphates via Imidophosphates and 1,3,2λ⁵-Oxazaphospholidines The 2-azidoalcohols 1 and 2 react with trialkyl phosphites to trialkyl (2-hydroxy-alkyl)imidophosphates 10, 14 , and 15 respectively, whereas the 2-azidoalcohols 3-7 yield the 2,2,2-trialkoxy-1,3,2λ⁵-oxazaphospholidines 16–22 under the same reaction conditions (Scheme 2). The dialkyl (2-hydroxyalkyl)amidophosphates 23, 25 , and 27–34 are obtained by the reaction of 10 , and 14–22 with water (Scheme 3 and 4). By reaction with alcohols, however, both the imidophosphates 10, 14 and 15 and the 1,3,2λ⁵-oxazaphospholidines 16–22 are transformed to aziridines 24, 26 , and 35–38 (Scheme 5). The reactions of the imidophosphates seem to proceed via 1,3,2λ⁵-oxazaphospholidines.     

Reactions of dithioxo‐1,3,2λ5,4λ5‐dithiadiphosphetanes with antimony(III) alkoxides

New antimony(III) derivatives of dithiophosphonic and trithiophosphoric acids 3a–c and 5 were obtained by the reactions of Lawesson's reagent 1a, its homologue 1b, and the isobutyl homologue of Davy's reagent 4 with antimony(III) alkoxides 2a–c. © 1999 John Wiley & Sons, Inc. Heteroatom Chem 10: 399–403, 1999     

Synthese,Struktur, Elektrochemie und optische Eigenschaften von alkinylfunktionalisierten 1,3,2‐Diazaborolen und 1,3,2‐Diazaborolidinen

Syntheses, Structures, Electrochemistry and Optical Properties of Alkyne‐Functionalized 1,3,2‐Diazaboroles and 1,3,2‐Diazaborolidenes The reaction of 2‐bromo‐1,3‐ditert‐butyl‐2,3‐dihydro‐1H‐1,3,2‐diazaborole ( 3 ) with lithiated tert‐butyl‐acetylene and lithiated phenylacetylene affords the 2‐alkynyl‐functionalized 1,3,2‐diazaboroles 4 and 5 as a thermolabile colorless oil ( 4 ) or a solid ( 5 ). Similarly 2‐bromo‐1,3‐diethyl‐2,3‐dihydro‐1H‐1,3,2‐benzodiazaborole ( 6 ) was converted into the crystalline 2‐alkynyl‐benzo‐1,3,2‐diazaboroles 7 and 8 by treatment with LiC≡C–tBu or LiC≡CPh, respectively. 2‐Ethynyl‐1,3‐ditert‐butyl‐2,3‐dihydro‐1H‐1,3,2‐diazaborole ( 2 ) was metalated with tert‐butyl‐lithium and subsequently coupled with 2‐bromo‐1,3,‐ditert‐butyl‐2,3‐dihydro‐1H‐1,3,2‐diazaborole ( 3 ) to afford bis(1,3‐ditert‐butyl‐2,3‐dihydro‐1H‐1,3,2‐diazaborol‐2‐yl)acetylene ( 9 ) as thermolabile colorless crystals. Analogously coupling of the lithiated species with 6 or with 2‐bromo‐1,3‐ditert‐butyl‐1,3,2‐diazaborolidine ( 11 ) gave the unsymmetrically substituted acetylenes 10 or 12 , respectively, as colorless solids. Compounds 4 , 5 , 7 – 10 and 12 are characterized by elemental analyses and spectroscopy (IR, ¹H‐, ¹¹B{¹H}, ¹³C{¹H}‐NMR, MS). The molecular structures of 5 , 8 and 9 were elucidated by X‐ray diffraction analyses.     

Darstellung von Bis‐(2‐chlorethyl)amino‐substituierten Diazaphosphorinonen. Reversible oxidative Addition von Hexafluoraceton an σ3λ3‐Phosphor‐Verbindungen. Synthese von σ5λ5‐Spirophosphoranen und deren Zersetzung

Synthesis of Bis‐(2‐chloroethyl)amino‐substituted Diazaphosphorinones. Reversible Oxidative Addition of Hexafluoroacetone to σ³λ³‐Phosphorus Compounds. Synthesis of σ⁵λ⁵‐Spirophosphoranes and their Decomposition The reaction of 1‐methyl‐pyrido[3,2‐e]‐3,1‐oxazin‐2,4‐dione ( 1 ) with benzylamines led to the aminonicotinic acid amides 2 – 4 . Their reaction with phosphorus trichloride furnished the P‐chloro‐pyridodiazaphosphorinones 5 – 7 , which, upon reaction with bis‐(2‐chloroethyl) ammonium chloride/triethylamine, were converted into the P‐bis‐(2‐chloroethyl)amino‐substituted pyridodiazaphosphorinones 8 – 10 . The P‐chloro‐benzodiazaphosphorinone 11 was allowed to react with 2‐chloroethylammonium chloride/triethylamine to form the 2‐chloroethylamino‐substituted derivative 12 . The σ³‐diazaphosphorinones 8 , 9 , 12 and 13 were oxidized with the urea‐hydrogen peroxide‐(1 : 1)‐adduct to the corresponding phosphoryl derivatives 14 – 17 . The oxidative addition of hexafluoroacetone (HFA) to the σ³‐diazaphosphorinone 18 led, with abstraction of methyl chloride, to the tricyclic phosphorane 19 b . The spirophosphoranes 21 – 23 were formed by reaction of compounds 8 , 9 and 13 with HFA. NMR‐studies were made on the decomposition of the bicyclic phosphoranes 20 a , 22 and 23 . The oxidative addition of HFA to diazaphosphorinones was found to be reversible. Single crystal X‐ray determinations were conducted on compounds 17 and 19 b . They confirm the expected connectivity. Compound 17 was found to exhibit short C–H‥ O‐hydrogen bonds (H…O 234 pm). Compound 19 crystallises as two independent molecules which differ, e. g., in the orientation of the chloroethyl groups.     

Reactions of dithioxo-1,3,2λ5,4λ5-dithiadiphosphetanes with triorganolead derivatives

The reactions of Lawesson's reagent 1a and its 4-ethoxy homologue 1b with triethyl- and triphenyl(alkoxy)plumbanes 2a,b and -(alkylthio)plumbanes 4a,b were studied. On the basis of these reactions, novel, advantageous methods of synthesizing S-triethyl and triphenylplumbyl derivatives of aryldithio- and trithiophosphonic acids 3a–d and 5a,b were developed. © 1997 John Wiley & Sons, Inc.     

Die Reaktion von λ5-Diphospheten mit COS und CO2 Dihydro-λ5-Phosphete

Reactions of λ⁵-Diphosphetes with COS and CO₂. Dihydro-λ⁵-Phosphetes 1,1,3,3-Tetrakis(dimethylamino)-1λ⁵,3λ⁵-diphosphete, 1 , reacts with COS to yield the (3-oxo-3,4-dihydro-1λ⁵-phosphete-2-yl)-phosphonothioic bis(dimethylamide) 7 . Reaction of dimethyl substituted 1 , i.e. 1,1,3,3-tetrakis(dimethylamino)-2,4-dimethyl-1λ⁵,3λ⁵-diphosphete 4 , with COS and CO₂ results in (3-oxo-2,3-dihydro-1λ⁵-phosphete-2-yl)-phosphonothioic bis(dimethylamide) 9 , and (3-oxo-2,3-dihydro-1λ⁵-phosphete-2-yl)-phosphonic bis(dimethylamide) 10 , respectively. Reaction mechanisms are suggested. 7, 9 and 10 are characterized by their properties, and their nmr, mass-, and ir-spectra. The results of X-ray structural analyses of 9 and 10 are reported and discussed.     

Molekül- und Kristallstruktur von 9λ4-Thia-2,4,6,8,10,11-hexaza-1λ5,3λ5,5λ5,7λ5-tetraphosphabicylo[5.3.1]undeca-1,3,5,7(11),8,9-hexaen,einem schwefeldiimidoüberbrückten Cyclotetraphosphazen

Molecular and Crystal Structure of 9λ⁴-Thia-2,4,6,8,10,11-hexaaza-1λ⁵,3λ⁵,5λ⁵,7λ⁵-tetraphosphabicylo[5.3.1]undeca-1,3,5,7(11),8,9-hexaene, Cyclotetraphosphazene Bridged by a Sulfur Diimide Group We have carried out an X-ray structure analysis of the title compound ( 1 ). 1 crystallizes in the monoclinic space group P2₁/b with a = 9.436(4), b = 20.102(7), c = 11.622(5) Å, γ = 103.52(8)°, Z = 8. There are two molecules in the asymmetric unit, which in approximation can be transformed one into the other by additional symmetry elements of a substructure of a space group B2/b. The S = N bond lengths are 1.53 Å. The P? N bonds connecting the SN₂ system are 1.666 Å long. They are significantly longer than the P? N multible bonds in the P₄N₄ ring within a range of 1.517 to 1.565 Å. The sulfur diimide unit and its substituents are coplanar causing a half-boat conformation of the heterocyclic six membered ring. The cyclotetraphosphazene ring shows a flattened crown-saddle conformation, the phosphorous atoms arranged nearly at the corners of a square. Influenced by crystal packing there exist small deviations from the molecular mirror plane and also differences in conformation between the two molecules of the asymmetric unit.     

Synthese von Fluoro-λ5-monophosphazenen und Fluoro-1, 3-diaza-2λ5, 4λ5-diphosphetidinen mittels der Staudinger-Reaktion

Synthesis of Fluoro-λ⁵-monophosphazenes and Fluoro-1,3-diaza-2λ⁵,4λ⁵-diphosphetidines by Means of the Staudinger Reaction 35 Tetrafluoro- and 2 difluorodiaza-diphosphetidines as well as 4 difluoro- and 30 monofluoro-λ⁵-monophosphazenes were prepared by the Staudinger reaction between tervalent phosphorus fluorides, R_nPF_3?n (n = 1, 2; R = R₂N, (CH₂)₅N, O(CH₂)₄N, RO, (CH₂O)₂, alkyl, aryl) and phenylazides, X? C₆H₄N₃ (X = H, 4-CH₃, 4-Cl, 4-Br, 4-NO₂, 3-NO₂). PF₃ does not react with phenylazide The influence of substituents on the structure of the reaction products is discussed. Kinetic measurements allowed to determine the constants λ^P_I of the substituents (CH₂)₅N, O(CH₂)₄N and R(C₆H₅)N (R = CH₃, C₂H₅, n-C₄H₉).     

Facile Synthesis and Properties of 2‐λ5‐Phosphaquinolines and 2‐λ5‐Phosphaquinolin‐2‐ones

Treatment of 2‐ethynylanilines with P(OPh)₃ gives either 2,2‐diphenoxy‐2‐λ⁵‐phosphaquinolines or 2‐phenoxy‐2‐λ⁵‐phosphaquinolin‐2‐ones under transition‐metal‐free conditions. This reaction offers access to an underexplored heterocycle, which opens up the study of the fundamental nature of the N?P^V double bond and its potential for delocalization within a cyclic π‐electron system. This heterocycle can serve as a carbostyril mimic, with application as a bioisostere for pharmaceuticals based on the 2‐quinolinone scaffold. It also holds promise as a new fluorophore, since initial screening reveals quantum yields upwards of 40 %, Stokes shifts of 50–150 nm, and emission wavelengths of 380–540 nm. The phosphaquinolin‐2‐ones possess one of the strongest solution‐state dimerization constants for a D–A system (130 M ^?1) owing to the close proximity of a strong acceptor (P?O) and a strong donor (phosphonamidate N? H), which suggests that they might hold promise as new hydrogen‐bonding hosts for optoelectronic sensing.     

Reactions of dithioxo-1,3,2λ5,4λ5-dithiadiphosphetanes with trialkylsilyl and stannyl derivatives

The reactions of homologues of Davy's reagent 1 and Lawesson's reagent 9 with trimethylalkylthiosilanes 2 , trimethylsilyl enol ether 4 , trimethyl(diethylamino)silane 7 , trialkylalkoxystannanes 14 , and trialkylalkylthiostannane 15 were studied. On the basis of these studies, novel advantageous methods of synthesizing S-trialkylsilyl and stannyl esters of tetrathio-, trithio-, and amidotrithiophosphoric acids 3 , 5 , 6 , and 4-methoxyphenyldithio- and trithiophosphonic acids 10–13 were developed