水杨酸与二烷基亚磷酸酯反应历程31P NMR与电喷雾质谱跟踪研究

The reaction between salicylic acid and dialkyl phosphite was traced by electrospray ionization mass spectrometry and ^31P NMR. All reactants, unstable intermediates and products were detected. The mechanism was proposed based on ESI-MS results and ^31P NMR profiles.     

Stabilization of Hydroxy Tautomeric Form of Dimethyl Phosphite in the Coordination Sphere of Carbonyl Complexes of Group VI Metals

The interaction of dimethyl phosphite with hexacarbonyls of the chromium group metals in a nonpolar solvent has afforded metal(0) σ⁴,λ⁴-(dimethyl phosphite)pentacarbonyls containing a hydroxy tautomeric form of dimethyl phosphite in the coordination sphere. Hydrogen of the phosphite OH group in the metal(0) σ⁴,λ⁴-(dimethyl phosphite)pentacarbonyls exhibited a significant acidity, strongest for the chromium complexes. Due to the significant acidity of the phosphite hydroxyl, the metal(0) σ⁴,λ⁴-(dimethyl phosphite)-pentacarbonyls are intermediates in the electrophilic version of the Pudovik reaction.     

Reaction of trimethyl phosphite with benzalacetophenone and benzal-α-tetralone

Conclusions Benzalacetophenone and benzal-α-tetralone when heated (50–60^o) for a long time with trimethyl phosphite form 1,2-oxa-4-phospholenes, which represent heat unstable compounds of pentacoordinated phosphorus. A. M. Butlerov Chemical Institute, V. I. Ul'yanov-Lenin Kazan State University. Translated from Izvestiya Akademii Nauk SSSR, Seriya Khimicheskaya, No. 10, pp. 2369–2371, October, 1976.     

The role of organic phosphite primary structure in the overall stabilization performance in polypropylene

The role of the primary P³⁺ functionality in the phosphite overall stabilization performance was re-evaluated. Tris(2,4-di-t-Bu-phenyl)phosphite (P-1) and its oxidation product tris(2,4-di-t-Bu-phenyl)phosphate (P-1_ox) were tested both alone and in the presence of hindered phenol during processing in polypropylene. Efficiencies were quantified using the processing degradation index (PDI). The position of the traditional multiple extrusion curve was determined by a single parameter, describing the degree of polymer degradation. Its reciprocal allowed calculating formulations relative efficiencies. It was shown that oxidation of P³⁺ into P⁵⁺ is responsible for 75 % phosphite stabilization performance, regardless phosphite acts alone or in combination with phenol. If P³⁺ is completely oxidized, stabilizer still works. For the residual performance, the reactions of 2,4-di-t-Bu-phenyl substituents (secondary structure), are responsible. Besides processing, reactions of P³⁺ also contribute to the long-term stability at 150 °C. Once phosphite is oxidized, the secondary structure does not contribute to the long-term stability at all.     

31P NMR study of the hydrolytic activity of ethriol phosphite and triphenyl phosphite in a two-phase system

The hydrolytic activity of ethriol phosphite and triphenyl phosphite in the p-xylene/water two-phase system was studied by the³¹P NMR method. It was shown that the rate of hydrolysis can be controlled by varying the pH of the aqueous phase. Hydrolysis of triphenyl phosphite is much slower than that of ethriol phosphite in the tested pH range. Coordination of ethriol phosphite with a rhodium carbonyl complex completely suppresses its hydrolysis.Translated from Izvestiya Akademii Nauk SSSR, Seriya Khimicheskaya, No. 5, pp. 1026–1030, May, 1991.     

Following the Reaction of Heteroanions inside a {W18O56} Polyoxometalate Nanocage by NMR Spectroscopy and Mass Spectrometry

By incorporating phosphorus(III)‐based anions into a polyoxometalate cage, a new type of tungsten‐based unconventional Dawson‐like cluster, [W₁₈O₅₆(HP^IIIO₃)₂(H₂O)₂]^8?, was isolated, in which the reaction of the two phosphite anions [HPO₃]^2? within the {W₁₈O₅₆} cage could be followed spectroscopically. As well as full X‐ray crystallographic analysis, we studied the reactivity of the cluster using both solution‐state NMR spectroscopy and mass spectrometry. These techniques show that the cluster undergoes a structural rearrangement in solution whereby the {HPO₃} moieties dimerize to form a weakly interacting (O₃PH???HPO₃) moiety. In the crystalline state the cluster exhibits a thermally triggered oxidation of the two P^III template moieties to form P^V centers (phosphite to phosphate), commensurate with the transformation of the cage into a Wells–Dawson {W₁₈O₅₄} cluster.     

Phosha-Meerwein Reaction of Diazo Esters

Abstract

Diazo esters (la,b) react with trialkyl phosphates (2a–c) in the presence of BF₃.OEt₂ to give the corresponding phosphates (3a–e) in 42–58 % yields. The competed intra/intermolecular protonation in the reaction of la with dimethyl hydrogen phosphite leads to phosphonate. 4,and phosphite 5.     

Dual Stereochemical Control in Reaction of Di- and Trialkyl Phosphites with Aldimines

Stereochemistry of addition of di- and trialkyl phosphites to C=N compounds was investigated. Reactions of achiral dialkyl phosphites with chiral aldimines as well as that of chiral di-(1R,2S,5R)-menthyl phosphite with achiral aldimines result in low diastereomeric enrichment of the addition compound. Reaction stereoselectivity increased when supplementary chiral inductor was introduced to the reaction system. Reaction of di-(1R,2S, 5R)-menthyl phosphite with (S)-α-methylbenzylbenzaldimine proceeds as concerted asymmetric induction to form practically one diastereomer of N-substituted aminophosphonic acid. However, reaction of di-(1R,2S, 5R)-menthyl phosphite with (R)-α-methylbenzylbenzaldimine proceeded as not concerted asymmetric induction, and diastereomeric enrichment of the product was low. By chemical extrapolation, absolute configuration of compounds formed was established. Tri-(1R,2S,5R)-menthyl phosphite reacts with C=N compounds in the presence of boron trifluoride etherate to form aminophosphonic acid derivatives with the absolute configuration opposite to that appearing in the reaction of di-(1R,2S,5R)-menthyl phosphite with the same C=N compounds.     

Fine‐Tuning the Reactivity and Stability by Systematic Ligand Variations in CpCoI Complexes as Catalysts for [2+2+2] Cycloaddition Reactions

CpCo^I‐olefin‐phosphite and CpCo^I‐bisphosphite complexes were systematically prepared and their reactivity in [2+2+2] cycloaddition reactions compared with highly active [CpCo(H₂C?CHSiMe₃)₂] ( 1 ). Whereas 1 is an excellent precursor for the synthesis of [CpCo(olefin)(phosphite)] complexes ( 2 a – f ), [CpCo(phosphite)₂] complexes ( 3 a – e ) were prepared photochemically from [CpCo(cod)]. The complexes were evaluated in the cyclotrimerization reaction of diynes with nitriles yielding pyridines. For [CpCo(olefin)(phosphite)], as well as some of the [CpCo(phosphite)₂] complexes, reaction temperatures as low as 50 °C were sufficient to perform the cycloaddition reaction. A direct comparison showed that the order of reactivity for the complex ligands was olefin₂>olefin/phosphite>phosphites₂. The complexes with mixed ligands favorably combine reactivity and stability. Calculations on the ligand dissociation from [CpCo(olefin)(phosphite)] proved that the phosphite is dissociating before the olefin. [CpCo(H₂C?CHSiMe₃){P(OPh)₃}] ( 2 a ) was investigated for the co‐cyclization of diynes and nitriles and found to be an efficient catalyst at rather mild temperatures.     

Reaction of derivatives of trivalent phosphorus with 2-oxo-1,3-dithio-1,3-diphenylpropane

Conclusions When trimethyl phosphite, tri(dimethylamino)phosphine, triphenylphosphine, and dimethylphosphorous acid are reacted with 2-oxo-1,3-dithio-1,3-diphenylpropane the latter is desulfurized and deoxidized.Translated from Izvestiya Akademii Nauk SSSR, Seriya Khimicheskaya, No. 9, pp. 2101–2103, September, 1976.The authors express their gratitude to É. L Gol'dfarb for taking the³¹P NMR spectra.     

On the mechanism of reaction of tert-butoxyl radicals with dialkylphosphites

It has been shown by ESR spectroscopy that the title reaction involves abstraction of hydrogen from the phosphite, since at ?10°C the reaction has a kinetic deuterium isotope effect, k_H/k_D, or ～3. The rate constant for hydrogen abstraction is c. 2 × 10⁴ M^?1 s^?1. There is no significant addition of alkoxyl radicals to the phosphite.     

Reaction of Triethyl Phosphite with Boron Tribromide

 Reaction of boron tribromide with triethyl phosphite led to the formation of triethyl tribromoborophosphate 1, a complex bearing a P→B bond.     

31P NMR Studies of Diethyl Phosphite Derived Nanocrystalline Hydroxyapatite

³¹P nuclear magnetic resonance (NMR) spectroscopy was used to determine the structure of the intermediate species of sol derived from triethyl phosphite, calcium diethoxide and acetic acid. NMR spectral data revealed that the reaction proceeds via a dialkyl phosphite intermediate. The use of a dialkyl phosphite precursor (diethyl phosphite) with calcium diethoxide eliminated the aging time required in triethylphosphite method and offered an effective sol-gel procedure for monophasic hydroxyapatite.     

The n.m.r. of paramagnetic complexes of vanadyl acetylacetonate with organic phosphites and hydroperoxides

The vanadium IV ion in vanadyl acetylacetonate (V^IV) forms labile paramagnetic complexes with organic phosphites in the first coordination sphere. The enthalpy of complex formation between V^IV and triphenyl phosphite was 2.6 kcal mol^?1. Complex formation enthalpies ΔH and the activation energies E of ligand (hydroperoxide) escape from the metal ion sphere were determined from the temperature dependence of paramagnetic broadening of the n.m.r. lines of hydroperoxides in the presence of vanadyl acetylacetonate. At low temperatures the phosphite sharply weakens the bond between the metal ion and hydroperoxide in the second coordination sphere (ΔH decreases fivefold). Taken in excess, phosphite displaces the hydroperoxide molecules from the coordination sphere of the V^IV ion and thus blocks it. The observed n.m.r. characteristics of the paramagnetic complexes explain, on the model level, the kinetic regularities of the reaction of hydroperoxides with phosphite catalysed by transient metal ions.     

Synthesis and selected reactions of ethyl 5-(1-chloroethyl)-2-methylfuran-3-carboxylate

Ethyl 2-methylfuran-3-carboxylate is smoothly chloroethylated at 0°C in the 5 position of the ring. The resulting halide alkylates secondary amines but eliminates HCl with sodium diethyl phosphite under the Michaelis-Becker reaction conditions and with trimethyl phosphite under the Arbuzov reaction conditions. In the reaction with sodium diethyl phosphite, small amounts of 5-[1-(diethoxyphosphoryl)ethyl]furan-3-carboxylate and 5-ethylfuran-3-carboxylate are formed. In the Arbuzov reaction at a 1: 1.22 furan: trimethyl phosphite molar ratio, methyl 2,4-dimethyl-1-methoxy-1-oxo-1λ⁵-1,2-dihydrophospheto[3,2-b]furan-5-carboxylate was isolated.     

Synthesis and characterization of the substituted products from the reaction of a bulky phosphite with [Os3(CO)12]

Reaction of (acetonitrile)-undeca(carbonyl)-tri-osmium and tris(2,4-di-tert-butylphenyl) phosphite yielded the phosphite clusters [Os₃(CO)₁₁L] (4) and [Os₃(CO)₁₀L₂] (5) [L = P(O-2,4- ^t Bu₂C₆H₃)₃]. These compounds were characterized spectroscopically and the molecular structure of 5 was determined by single crystal X-ray diffraction, the first reported structural analysis of a tri-osmium cluster containing aromatic phosphite ligands. Compound 5 crystallized in the triclinic space group P 1, and revealed an equatorial trans–trans position of the bulky phosphite ligands.     

Ligand exchange reactions with η6-arene-η5-cyclopentadienyliron cations under thermal or photochemical conditions

Reactions of various η⁶-arene-η⁵-cyclopentadienyliron or substituted cyclopentadienyliron cations with trimethyl, triethyl or triphenyl phosphite under either thermal or photochemical conditions all resulted in the replacement of the arene ligand with three phosphite ligands to give η⁵-tris(trimethyl, triethyl or triphenyl phosphite)-η⁵-cyclopentadienyliron or substituted cyclopentadienyliron cations. The yields of the phosphite complexes were higher from photolysis than from the analogous thermolysis. Photolysis of the η⁶-chlorobenzene-η⁵-cyclopentadienyliron cation (IX) carried out in the presence of a more basic or more electron-rich aromatic ligand resulted in the exchange of the chlorobenzene of IX with the more basic arene, thus providing synthetic routes to cyclopentadienyliron complexes that may be difficult to prepare by other means. New complexes synthesized in this way are the η⁶-2-phenylethyl tosylate-η⁵-cyclopentadienyliron cation and the CpFe⁺ complexes of thiophene, 2-methylthiophene, 3-methylthiophene and 2,5-dimethylthiophene.     

Structure of products from the transesterification of triethyl phosphite with pentitols

Conclusions The differences in the³⁴P NMR spectra of the isomeric triphosphites C₁₃H₂₇O₉P₃ which are formed by transesterification of triethyl phosphite with pentitols are caused by the different configurations of the ethyl phosphite rings.Translated from Izvestiya Akademii Nauk SSSR, Seriya Khimicheskaya, No. 4, pp. 847–850, April, 1988.     

Reaction of N-Phtalylamino Acid Chlorides with Trialkyl Phosphites

Abstract

Reaction of N-blocked amino acid chlorides with trialkyl phosphites is a first step in the synthesis of 2-amino-l-hydroxyalkylphosphonates. Quite surprisingly a very purl trialkyl phosphite is required m order to obtain the desired N-blocked 2-amino-1-oxoalkylphosphonate. Thus, the use of commercially rvailrble phosphites prolongation of the reaction time, or attempts for chromatographic purification of the formed oxophosphonate resulted m quite complicated mixture of products. We haw found that these products arise as a consequence of rearrangements of 1oxo-2. phtalylnmmoalLylphosphonates in a series of reactions which are promoted by that presence of dialkyl phosphite (standard impurity present m commercially availablt trialkyl phosphites) in the reaction medium.     

Synthesis and Spectral Characterization of Some Novel Phosphonyl‐ and Phosphoryl Pyrazole Compounds

1,3‐Diphenyl‐1H‐pyrazole‐4‐carbaldehyde ( 1 ) reacted with aniline, 2‐substituted anilines, and P,P‐dimethylphosphinic hydrazide in the presence of diethyl phosphite to give acyclic α‐aminophosphonate 2 , cyclic α‐aminophosphonates 4–6 , and α‐hydrazinophosphonate 7 , respectively. Also, treatment of aldehyde 1 with cyanoaceto‐hydrazide, acetophenone, and malononitrile afforded the condensation products 8 , 16 , and 21 , respectively, which in turn, reacted with diethyl phosphite and P,P‐dimethylphosphinic hydrazide. The reaction of diethyl phosphite with the hydrazone 8 and chalcone 16 yielded the novel phosphorus heterocycles 13 and 18 , respectively, while its reaction with the dicyanoarylidene 21 produced the dicyanopyrazolyl phosphonate 22 . On the other hand, treatment of the hydrazone 8 with P,P‐dimethylphosphinic hydrazide gave the unexpected P,P‐dimethylphosphinic hydrazone 15 , which reacted with diethyl phosphite forming α‐hydrazinophosphonate 7 . Furthermore, the interesting N‐phosphoryl pyrazoles 20 and 24 were resulted in good yield via cycloaddition of P,P‐dimethylphosphinic hydrazide to the chalcone 16 and dicyanoarylidene 21 , respectively. Structures of all newly synthesized compounds were confirmed by considering the data of IR spectroscopy, MS, and ¹H‐, ¹³C‐, and ³¹P‐NMR spectroscopy, as well as that of elemental analyses.