Pyridine 2,4,6-triphenyl

Decaborane reacts with pyridine, triphenyl phosphine, triethylamine, acetonitrile and other weak bases forming an adduct with liberation of hydrogen ... 

We have noted that N-bonded thiocyanate complexes dissociate readily in solution. Mixed ligand complexes of lanthanides with thiocyanates and L = ethanol, pyridine, triphenyl phosphorous oxide, phenanthroline, etc. have been synthesized. 

The activity in MMA polymerization can be dramatically affected by the apical ligands. Apical aquo or alcohol ligands are labile and rapidly exchange with the polymerization medium. Lewis base ligands (e.g. pyridine, triphenyl phosphine) are comparatively stable. In MMA polymeri/ation, it is found that activity increases with the basicity of the ligand. With alkyl Co " complexes, a different order is found possibly because the type of apical ligand also controls the rate of initial generation of the active Co" complex. 

The relatively stable (arylsulfonylmethyl)iodonium salts 763 (Section 2.1.9.5) are efficient electrophilic alkylating reagents towards various organic nucleophiles (thiophenolate anion, amines, pyridine, triphenyl phosphine and silyl enol ethers). All these reactions proceed under mild conditions and selectively afforded the appropriate product of alkylation along with iodobenzene as the by-product (Scheme 3.299) [1016]. 

The aromatic heterocycle phosphabenzene C5H5P (analogous to pyridine) was reported in 1971, some years after its triphenyl derivative 2,4,6-Ph3C5H2P. See also HP=CH2 29) nd [P(CN)2] ° (p. 484). The burgeoning field of heterocyclic phosphorus compounds featuring... 

An early example of N/C replacement leading to a pyrimidine-pyridine conversion is observed on thermolysis (240 °C) of 2,4,6-triphenyl-4-methyl-3,4-dihydropyrimidine. During the thermolysis ammonia evolves and in... 

This method involves the direct polycondensation of aromatic diamines with aromatic diacids in the presence of an aryl phosphite (triphenyl phosphite) and an organic base like pyridine.7,9 70 71 The addition of salts improves die solubility of the polymer and, with this, the maximum attainable molecular weight.71 The concentrations are, however, lower than by the dichloride method. 

Pyridin-1-oxide werden durch Triphenyl-phosphan zu Pyridinen desoxygeniert2 analog bildet 3,4-Dihydro-chinolin- 1-oxid 3,4-Dihydro-chinolin (s.Bd. X/4, S. 439). 

By analogy with the cyclotrimerization of acetylenes into arenes, and with the cocyclooligomerization of nitriles and acetylenes into pyridines (see Scheme 131 in Section V,A,1), the cyclization of benzonitrile into 2,4,6-triphenyl-s-triazine can be achieved by means of Fe(CO)5 or Fe2(CO)9.241... 

Triphenyl phosphite can be prepared by the gradual addition of phosphorus trichloride to a mixture of phenol and pyridine.6 It is claimed that magnesium chloride can be used in place of pyridine.7... 

EINECS 203-468-6, see Ethylenediamine EINECS 203-470-7, see Allyl alcohol EINECS 203-472-8, see Chloroacetaldehyde EINECS 203-481-7, see Methyl formate EINECS 203-523-4, see 2-Methylpentane EINECS 203-528-1, see 2-Pentanone EINECS 203-544-9, see 1-Nitropropane EINECS 203-545-4, see Vinyl acetate EINECS 203-548-0, see 2,4-Dimethylpentane EINECS 203-550-1, see 4-Methyl-2-pentanone EINECS 203-558-5, see Diisopropylamine EINECS 203-560-6, see Isopropyl ether EINECS 203-561-1, see Isopropyl acetate EINECS 203-564-8, see Acetic anhydride EINECS 203-571-6, see Maleic anhydride EINECS 203-576-3, see m-Xylene EINECS 203-598-3, see Bis(2-chloroisopropyl) ether EINECS 203-604-4, see 1,3,5-Trimethylbenzene EINECS 203-608-6, see 1,3,5-Trichlorobenzene EINECS 203-620-1, see Diisobutyl ketone EINECS 203-621-7, see sec-Hexyl acetate EINECS 203-623-8, see Bromobenzene EINECS 203-624-3, see Methylcyclohexane EINECS 203-625-9, see Toluene EINECS 203-628-5, see Chlorobenzene EINECS 203-630-6, see Cyclohexanol EINECS 203-632-7, see Phenol EINECS 203-686-1, see Propyl acetate EINECS 203-692-4, see Pentane EINECS 203-694-5, see 1-Pentene EINECS 203-695-0, see cis-2-Pentene EINECS 203-699-2, see Butylamine EINECS 203-713-7, see Methyl cellosolve EINECS 203-714-2, see Methylal EINECS 203-716-3, see Diethylamine EINECS 203-721-0, see Ethyl formate EINECS 203-726-8, see Tetrahydrofuran EINECS 203-729-4, see Thiophene EINECS 203-767-1, see 2-Heptanone EINECS 203-772-9, see Methyl cellosolve acetate EINECS 203-777-6, see Hexane EINECS 203-799-6, see 2-Chloroethyl vinyl ether EINECS 203-804-1, see 2-Ethoxyethanol EINECS 203-806-2, see Cyclohexane EINECS 203-807-8, see Cyclohexene EINECS 203-809-9, see Pyridine EINECS 203-815-1, see Morpholine EINECS 203-839-2, see 2-Ethoxyethyl acetate EINECS 203-870-1, see Bis(2-chloroethyl) ether EINECS 203-892-1, see Octane EINECS 203-893-7, see 1-Octene EINECS 203-905-0, see 2-Butoxyethanol EINECS 203-913-4, see Nonane EINECS 203-920-2, see Bis(2-chloroethoxy)methane EINECS 203-967-9, see Dodecane EINECS 204-066-3, see 2-Methylpropene EINECS 204-112-2, see Triphenyl phosphate EINECS 204-211-0, see Bis(2-ethylhexyl) phthalate EINECS 204-258-7, see l,3-Dichloro-5,5-dimethylhydantoin... 

Replacement of an allylic hydroxyl without saturation or a shift of the double bond was achieved by treatment of some allylic-type alcohols with triphenyliodophosphorane (PhjPHI), triphenyldiiodophosphorane (PhsPIj) or their mixture with triphenyl phosphine (yields 24-60%) [612]. Still another way is the treatment of an allylic alcohol with a pyridine-sulfur trioxide complex followed by reduction of the intermediate with lithium aluminum hydride in tetrahydrofuran (yields 6-98%) [67 J]. In this method saturation of the double bond has taken place in some instances [675]. 

The triphenyl derivative (91, R = R = R = Ph, R = H) is formed in a mechanistically interesting reaction between benzoyl formic acid anil (Ph-N=CPh-C02H), trifluoroacetic anhydride, and pyridine. Its 1,3-dipolar cycloaddition reactions with alkynes and alkenes have been reported. ... 

Investigation of template poly condensation kinetics has only been studied within a very narrow scope. Polymerization of dimethyl tartrate with hexamethylene diamine was found to be enhanced by using as a template poly(vinyl pyrrolidone), poly(2-vinyl pyridine), or polysaccharides and poly(vinyl alcohol), poly(4-vinyl pyridine). In this case, the template can be treated as a catalyst. No information exists on the influence of the template on the order of reaction. The increase in molecular weight of the polymerization product by the template can be induced by a shift of equilibrium or by an increase in the reaction rate. A similar increase in the reaction rate was observed when poly(4-vi-nyl pyridine) was used in the synthesis of poly(terephtalamides) activated by triphenyl phosphite.The authors suggested that a high molecular weight template was involved in the increase of the local concentration of the substrate (terephthalic acid) by adsorption and activation via N-phosphonium salt of poly(4- vinyl pyridine). 

This development encourj d further attempts to synthesize a neutral system with a delocalized P—C double bond, which — by analogy to pyridine - could be termed phosphorin or, more systematically, phosphahenzene. G. Markl (1966) first succeeded in preparing 2.4.6-tri-phenylphosphabenzene 2, or as we shall call it, 2.4.6-triphenyl- -phosphom. 

Our attempts as well as those of C. C. Price to react 2.4.6-triphenylpyry-lium salts with phosphine, phenylphosphine or tris-hydroxymethyl-phosphine in the hope of isolating phosphorins or their P-substituted derivatives were unsuccessful. In contrast, MarM applying essentially the same principle but using pyridine as base and solvent, succeeded by heating 2.4.6-triphenylpyrylium-tetrafluoro-borate 21 with tris-hydroxymethyl-phosphine 5. He was able to isolate 2.4.6-triphenyl-X -pbosphorin 22, m. p. 171—172 C, as the first X -phosphorin in 20-25% yield. 

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