Fluoridolyse von Cyclophosphazenen und linearen Polyphosphazenen

Fluoridolysis of Cyclophosphazenes and Lineary Polyphosphazenes The fluorination of nongeminal trans P₃N₃Cl₄(NEt₂)₂ and nongeminal trans P₃N₃Cl₃(NEt₂)₃ with the fluorination agent Et₃N · 0,6 HF ( B ) occurs under retention of configuration yielding P₃N₃Cl₂F₂(NEt₂)₂ and P₃N₃F₄(NEt₂)₂ or P₃N₃F₃(NEt₂)₃, respectively. P₃N₃Cl₆ is nearly quantitatively converted into P₃N₃F₆. Poly(dichlorophosphazene) reacts to a poly(difluorophosphazene), (PNF₂)_n, distinguished by a moderate solubility in THF.     

Fluoridolyse von Diphosphorylverbindungen

Fluoridolysis of Diphosphoryl Compounds The behaviour of diphosphoryl compounds [X₂(O)P]₂Y in fluoridolysis reactions is decisively determined by the nature of the bridging group Y. In the cases of Y = NH and CH₂ and X = Cl [F₂P(O)]₂N^? and [F₂P(O)]₂CH₂ are obtained quantitatively. For Y = NPh, O, and CH₂ the formation of phosphorylated pentafluorophosphates [F₅P? Y? POX₂]^? is observed. Amido and ester derivatives containing fluorine (see table 2) are obtained from the corresponding chloro compounds by Cl/F exchange. Fluoridolysis of the azadiphosphetidine 19 results in the formation of acyclic 19 a .     

Zur Reaktion von Fluorphosphanen mit Silylaziden

On the Reaction of Fluorophosphanes with Silylazides . The fluorophosphanes Ph₂PF ( 1 ), PhOPF₂ ( 2 ), C₅H₁₀NPF₂ ( 3 ), (Et₂N)PF₂ ( 4 ), and (Et₂N)₂PF ( 5 ) react with Me₃SiN₃ via azidophosphanes R_3?nP(N₃)_n to oligo- and polyphosphazenes, (RR′P?N)_n. (ⁱPr₂N)₂PF ( 6 ), however, is oxidized by Me₃SiN₃ yielding the N-silylated phosphazene (ⁱPr₂N)₂PF?N? SiMe₃ ( 7 ). ^tBuPh₂SiN₃ is considerably less reactive. On contrary to Me₃SiN₃ it even oxidizes 5 and 1 forming (Et₂N)₂FP?N? SiPh₂^tBu ( 10 ) and Ph₂FP?N? SiPh₂^tBu, resp.     

Fluorierung von Dioxa- und Oxazaphospholanen

Fluorination of Dioxa- and Oxazaphospholanes The fluoridolysis of cyclic esters and esteramides of phosphorous acid ( 1 , 2 , 4 , 5 , 7 , 11 , and 12 ,) using the acid fluorination reagent Et₃N · nHF (n > 1) or an excess of a basic composed agent (n < 1) yields in all cases HPF₅^? ( 3 ,). With stoichiometric amounts of fluoride, however, the fluorophospholanes ( 4 ,) and ( 5 ,) as well as fac.- and mer.-o- ( 6a, 6b ,) and the spirocyclic fluorohydridophosphate ( 8 ,) are obtained. ( 13 ,) reacts to ( 14 ,) and the spirocyclic compound ( 15 ,) gives ( 16 ,). The fluorophosphoranes ( 18 ,), ( 19 ,), and ( 21 ,) are obtained by oxidative fluorination of the spiro- or bicyclic P? H compounds 11, 12 , and 20 , with CCl₄/Et₃N · nHF (n < 1). The oxidative fluorination of the cyclic triesters of phosphorous acid 7 , and 23 , leads to the cyclic fluorophosphates ( 22 ,) and 16 , as well as 6. , The compounds 18, 19 , and 22 , are also formed by oxidative fluorination of elemental phosphorus, P₄, in the presence of the corresponding bifunctional nucleophile.     

Synthese,Komplexbildung und Kristallstrukturen von Cyclotriphosphazenen mit N,N,N′,N′‐Tetramethylguanidingruppen

Synthesis, Complex Formation, and Crystal Structures of Cyclotriphosphazenes with N,N,N′,N′‐Tetramethylguanidine Groups The reactions of monochloropentaphenoxycyclotriphosphazene and hexachlorocyclotriphosphazene with N,N,N′,N′‐tetramethylguanidine yield the mono and tetra substituted products 2‐(N,N,N′,N′‐tetramethylguanidine)‐2,4,4,6,6‐pentaphenoxy‐2 λ⁵,4 λ⁵,6 λ⁵‐cyclotriphosphaza‐1,3,5‐trien ( 1 ) and 2,2‐dichlor‐4,4,6,6‐tetra‐(N,N,N′,N′‐tetramethylguanidine‐2 λ⁵,4 λ⁵,6 λ⁵‐cyclotriphosphaza‐1,3,5‐trien ( 2 ) respectively; no hexa functionalized product could be obtained, even with high excess of the nucleophile. Electron release from the exocyclic amino substituent reduces the acceptor ability of the phosphorus atoms. Reactions of ( 2 ) with copper(II) chloride and palladium(II) bis(acetonitrilo)dichloride yield metal complexes with a ligand : metal ratio of 1 : 2. The X‐ray structure analyses of N₃P₃Cl₂(NC(N(CH₃)₂)₂)₄ · 2 CuCl₂ ( 2 a ) and N₃P₃Cl₂(NC(N(CH₃)₂)₂)₄ · 2 PdCl₂ ( 2 b ) show that each metal atom is coordinated by two imino nitrogen atoms in geminal positions and two chloride atoms in a square planar arrangement.     

Synthese,Komplexbildung und Kristallstrukturen von Cyclotriphosphazenen mit Pyridylalkylaminogruppen

Synthesis, Complex Formation and Crystal Structures of Cyclotriphosphazenes with Pyridylalkylamino Groups A variety of cyclotriphosphazenes with different numbers and types of functional pyridylalkylamino groups were synthesized by reactions of chlorophosphazenes with aminoalkylpyridine derivatives and completely characterized. The molecular structures of one multifunctional N‐donor ligand, N₃P₃(OC₆H₅)₅(NHCH₂CH₂C₅H₄N‐2) ( 1 ), was determined by X‐ray structure analysis. The hexafunctionalized derivative N₃P₃(NHCH₂CH₂C₅H₄N‐2)₆ ( 10 ) reacts with dichloromethane to form the HCl salt ( 10 a ) the structure of which could also determined by X‐ray crystal structure analysis. Complex formation of N₃P₃(OC₆H₅)₅(NHCH₂C₅H₄N‐3) ( 2 ) with cobalt(II) chloride yields the cobalt complex ( 2 a ) in which two molecules of the ligand are bonded to the tetrahedraly coordinated cobalt atom by the pyridine nitrogen atoms. The tetra functionalized ligand gem‐N₃P₃(OC₆H₅)₂(NHCH₂CH₂C₅H₄N‐2)₄ ( 8 ) forms the dinuclear cobalt‐cobaltate complex ( 8 a ) by interactions of a phosphazene nitrogen atom and the pyridine atoms of two cis‐vicinal functional groups with a CoCl unit and a pyridine group with a CoCl₃‐unit.     

Synthese und Kristallstrukturen von Quecksilber(II)-iodid-Komplexen mit 3- und 4-pyridylmethylamino- sowie 4-pyridylmethoxy-substituierten Cyclophosphazen-Liganden

Synthesis and Crystal Structures of Mercury(II) Iodide Complexes with 3- and 4-Pyridylmethylamino- and 4-Pyridylmethoxy Substituted Cyclophosphazene Ligands Multifunctional cyclophosphazene ligands with 2-, 3-, and 4-pyridylalkylamino- or 4-pyridylmethoxy groups, N₃P₃(OC₆H₅)₅(NHCH₂(C₅H₄N-2)) ( 1 ), N₃P₃(OC₆H₅)₅ · (NHCH₂(C₅H₄N-3)) ( 2 ), N₃P₃(OC₆H₅)₅(NHCH₂(C₅H₄N-4)) ( 3 ) and N₃P₃(OC₆H₅)₅(OCH₂(C₅H₄N-4)) ( 4 ) are accessible through reactions of monochlorpentaphenoxycyclotriphosphaza-1,3,5-trien with aminomethylpyridine or pyridyl methanolate. 1 does not react with mercury(II) iodide whereas 2–4 yield the metal complexes 2 a , 3 a , and 4 a by interactions of the pyridyl nitrogen atoms. The X-ray single crystal structure analyses of these compounds shows that 2 a and 4 a are dimers, whereas 3 a is a HgI₂ polymer with syndiotacticaly arranged ligands.     

NMR Studies of the Phosphazene/Phosphazane Rearrangement

In compounds such as hydroxy, methoxy and ethoxycyclophosphazenes a phosphazene/ phosphazane rearrangement occurs. In this process the electronic structure of the PN ring system changes under reduction of the endocyclic double bonds. A decrease of the s bond order of the PN bondings results in a decrease of the scalar couplings ¹J_PN and ²J_PP. In addition, considering the solid‐state ³¹P NMR spectra, significant differences between the phosphazene and phosphazane forms can be observed caused by a change of the local symmetry at the phosphorus atom. In the case of cyclotriphosphazenes a local C_2v symmetry exists (strictly valid for these compounds only) and the shielding (shift) tensor is characterized by a small anisotropy as well as a small axiality. Contrary to this in phosphazanes the phosphoryl bond is dominating the chemical shift tensor, characterized by a double to triple anisotropy and a high axiality. Quantum chemical GAUSSIAN calculations reflect these differences between phosphazenes and phosphazanes.     

Herstellung von Fluorophosphaten,Difluorophosphaten, Fluorophsophonaten und Fluorophosphiten in fluoridhaltigen Harnstoffschmelzen

Preparation of Fluorophosphates, Difluorophosphates, Fluorophosphonates, and Fluorophosphites in Fluoride-containing Urea Melts Phosphoric acid, phosphonic acid, and organylphosphonic acid react on heating in fluoride-containing urea melts in high yields to fluorophosphates, MPHO₂F, organylfluorophosphonates, M¹RPO₂F, organylpolyfluorophosphonates, MR¹CX(PO₂F)₂, MN(CH₂PO₂F)₃, and phosphonoorganylfluorophosphonates, MR¹CX(PO₃)PO₂F (M¹ = K, NH₄; R = organic substituent; R¹ = H, organic substituent; X = OH, NH₂, NR₂). The reaction mechanism of the formation of fluorophosphate ions in fluoride containing urea melts is discussed.     

The Reaction of the Bis-spirocyclic Phosphazene [N 3 P 3 (O 2 C 12 H 8 ) 2 Cl 2 ] (O 2 C 12 H 8 = 2,2′-Dioxybiphenyl) with Thiophenols,in the Presence of Alkali Carbonates

The reactions of the spirocyclic phosphazene [N 3 P 3 (O 2 C 12 H 8 ) 2 Cl 2 ] (O 2 C 12 H 8 = 2,2'-dioxybiphenyl) with the thiophenols HS--C 6 H 4 --R and M 2 CO 3 (M = K or Cs) in refluxing acetone gave respectively the spirocyclic substituted derivatives [N 3 P 3 (O 2 C 12 H 8 ) 2 (SC 6 H 4 --R) 2 ] R = H ( 2a ), Br ( 2b ), OMe ( 2c ), NO 2 ( 2d ). The reaction is a two-step process the second of which is much faster than the first and the monosubstituted intermediate [N 3 P 3 (O 2 C 12 H 8 ) 2 (SC 6 H 4 --R)Cl] cannot be detected. By contrast, in the analogous reactions with the phenols HO--C 6 H 4 --R and M 2 CO 3 (M = K or Cs) in acetone or THF, to give the known derivatives [N 3 P 3 (O 2 C 12 H 8 ) 2 (OC 6 H 4 --R) 2 ], the first step is faster although both are very dependent on R, M and the solvent. Thus, in the case of the phenol HO--C 6 H 4 --OMe the reaction conditions could be adjusted to give the useful synthetic intermediate monosubstituted derivative [N 3 P 3 (O 2 C 12 H 8 ) 2 (OC 6 H 4 --OMe)Cl] ( 3 ). The reaction of [N 3 P 3 (O 2 C 12 H 8 ) 2 Cl 2 ] with the bifunctional reagent mercaptophenol HS--C 6 H 4 --OH was not specific and led to mixtures of cyclic and oligomeric products.     

Synthesis and Crystal Structure of a P-Hydridophosphoraniminato–Zirconium Complex and Reaction to the First Tris(hydrido)cyclotriphosphazene

The first oligomeric phosphazene in which each phosphorus center features a PH functionality ( 3 ) was obtained from the amidophosphane 1 or its zirconium complex 2 .     

From neutral iminophosphoranes to multianionic phosphazenates. The coordination chemistry of imino-aza-P(V) ligands

This review deals with the chemistry and coordination behaviour of imino-aza phosphorus(V) ligands focussing on s- and p-block as well as Group 11 and 12 metal complexes. Imino phosphorus(V) ligands contain one or more terminal RNP-units, which include iminophosphoranes R₃PNR′, monoanionic diiminophosphinates [R₂P(NR′)₂]⁻, dianionic triiminophosphonates [RP(NR′)₃]²⁻ and trianionic tetraiminophosphates [P(NR′)₄]³⁻. Aza-phosphorus(V) ligands feature bridging PNP units, which include cyclic and polymeric phosphazenes [R₂PN]_n. Imino-aza- phosphorus(V) ligands containing both imino and aza functions include linear diiminodiphosphazenates [N{R₂P(NR′)₂}₂]⁻ and multianionic poly(imino) cyclophosphazeantes such as [N₄{RP(NR′)}₄]⁴⁻ and [N₃{P(NR′)₂}₃]⁶⁻. Imino-aza phosphorus(V) ligands are assembled of three basic building blocks: the cationic tetravalent phosphonium centre (P), the anionic divalent amido function (N) and the terminally arranged R-group. The overall negative charge Z of the resulting ligand system is equal to the difference between the number of P and the number of N-centres: Z=n(P)n(N). Imino-aza phosphorus(V) ligands are electron rich N-donor ligands which co-ordinate via both N(imino) and N(aza) functions and have been applied in numerous metal complexes in order to stabilise low coordination numbers, unusual oxidation states and bonding modes or serve as ligands in homogeneous catalysis. The R-group provides both steric bulk and solubility in non-polar solvents. Multianionic phosphazenates feature a polydentate ligand surface, which facilitates an extremely high metal load. PN units of iminophosphoranes and phosphazenes have acceptor properties and enhance the acidity of α-alkyl and ortho-aryl protons. Deprotonation of P-alkyl and P-aryl iminophosphoranes give ligand systems featuring C,N chelating sites, which are also discussed.     

Syntheses and Structures of Trilithium Cyclotriphosphazenates Equipped with 2‐Halo‐aryl Substituents

Hexakis (2‐halo‐anilino) cyclotriphosphazenes (2‐X‐C₆H₄NH)₆P₃N₃ {X = F ( 1d ), Cl ( 1e ), Br ( 1f )} were prepared by refluxing mixtures of hexachloro cyclotriphosphazene, 2‐haloaniline and triethylamine in toluene and characterized by single crystal X‐ray diffraction. 1d , 1e and 1f were reacted with ⁿBuLi in thf. Reactions were monitored with ³¹P NMR. Addition of three equivalents of ⁿBuLi yields lithium complexes of trianionic phosphazenates [{(thf)₂Li}₃{(2‐X‐C₆H₄N)₃(2‐X‐C₆H₄NH)₃P₃N₃}] {X= F ( 2d ), Cl ( 2e ) and Br ( 2f )}. 2d , 2e and 2f were structurally characterized by X‐ray diffraction, which reveals monomeric cis‐metalated phosphazenates featuring central P₃N₃ ring systems of chair conformation. Lithium ions reside in three N(eq)‐P‐N(endo) chelation sites at one face of the P₃N₃ ring system. Li…X distances are rather long (> 3Å) indicating no Li‐X interactions.     

Synthesis and Biological Activities of N-Phosphoryl Branched Peptides

Much research has shown that some N-phosphoryl peptides are endowed with important biological activities. For instance, Na-(diaryloxyphosphoryl)-L-alanyl-L-prolines are moderate inhibitors of angiotensin converting enzyme and yield highly potent inhibitors when they hydrolyze under physiological condition lossing 1 mol phenol1; Phosphoramido (N-[(a-rhamnopyranosyloxy)hydroxyphosphinyl]-L-Leu-L-Trp) and its analogues have been shown to be inhibitors of endothelin converting enzyme, therefor…     

Analysis of Hydrolysis Reaction of N-Phosphoryl Phenylalanine by HPLC-ESI-MS／MS

Hydrolysis procedure of N-phosphoryl phenylalanine (DIPP-Phe) was studied by HPLC-ESI-MS/MS. The results showed that (HO)(i-PrO)P(O)Phe was the main intermediate and the hydrolysis of DIPP-Phe also occurred through a penta-coordinate transition state.     

Synthesis of N-Phosphoryl Branched Peptides

H-phosphonates were conveniently prepared by direct transesterification of diphenyl phosphite (DPP) with the corresponding alcohols, without further purification they were reacted with branched peptide methyl ester (L-Leu2-L-LysOMe) through Atherton-Todd method, a series of different substituted alkyloxy (N-phosphoryl-L-Leu)2-L-LysOMe were synthesized, and their stmctures were confirmed by ^31P NMR, ESI-MS, ^1H NMR, ^13C NMR, IR and elemental analysis. The approach possesses the advantages of easy operation, high yield and inexpensive phosphorylating reagent.     

Interactions of oxidative radicals with N-phosphoryl dipeptide derivatives

The interactions of oxidative radicals (Br2 , HO etc.) with N-phosphoryl dipeptide derivatives (NDM-TrpOMe and NDT-MetOMe) have been investigated by using pulse radiolysis at different pH values. Ithas been found that Br2 and HO radicals oxidize the Met-site and Trp-site in the dipeptide derivatives via formation of the three-electron-bonded intermediate and indolyl radical simultaneously. Then the intramolecular electron transfer along the peptide backbone occurs. The rate constants of electron transfer, k, have been determined and the reaction mechanism has been deduced.     

Poly(organophosphazenes)--unusual new high polymers.

An inorganic-backbone high polymer system based on alternating phosphorus and nitrogen atoms promises to solve many of the problems hitherto associated with conventional organic polymers. The chemistry, structure, biomedical, and technological aspects of these polymers are reviewed.     

The Synthesis and Characterization of Aryloxy-Linear Phosphazenes

The reactions of N-dichlorophosphoryl-P-trichloromonophosphazene with sodium o-methylphenoxide, sodium p-methylphenoxide, sodium f -naphthalenoxide, monosodium 4-(2-pyridylazo)resorcinol, and sodium 1-nitroso-2-naphthaleneoxide have been investigated. Experimental studies were carried out in argon atmosphere. The sodium aryloxides were prepared from naphthalene or phenol derivatives and metallic sodium. The phosphazene and phenolate or naphthaleneoxide were reacted at 0°;C and then refluxed. After the reaction products were separated by using column chromatography, the structures of the compounds were defined by elemental analysis, IR, 1 H, 13 C, 31 P NMR, and mass spectroscopy. Tetra- and pentasubstituted monophosphazenes were obtained from sodium o-methylphenoxide. Pentasubstituted derivatives also were obtained from sodium p-methylphenoxide and sodium f -naphthaleneoxide. Phosphazene or any phosphorus compound could not be isolated from the reaction of phosphazene with monosodium 4-(2-pyridylazo)resorcinol and sodium 1-nitroso-2-naphthaleneoxide.     

Synthesis and characterization of cyclophosphazene complexes of zirconium(IV)

Cyclophosphazene complexes of zirconium(IV) of the types and (R =??Ph or –SiMe₃, n =?1 or 2) have been synthesizedand isolated by reactions of acyclic bis-silylated phosphazene, [HN(PPh₂NSiMe₃)₂], or bis-phenylated phosphazene, [HN(PPh₂NPh)₂], with ZrCl₄ or ZrCl₂(OPrⁱ)₂ in different stoichiometries under anhydrous and inert conditions. These cyclozirconatriazadiphosphorines have been characterized by elemental analyses (C, H, N, Cl and Zr), molecular weight determination, IR and NMR (¹H, ¹³C and ³¹P) spectral studies, which indicated the monomeric nature of these complexes and a bidentate mode of bonding by the phosphazene ligand, leading to trigonal bipyramidal or octahedral geometries around the zirconium.