Phosphines phosphorous acid ester

Most common is the preparation of alkyl phosphonic acid esters (phospho-nates) 4 (Z,Z = OR) from phosphorous acid esters (phosphites) 1 (Z,Z = OR). The preparation of phosphinic acid esters (Z = R, Z = OR) from phosphonous acid esters, as well as phosphine oxides (Z,Z = R) from phosphinous acid esters is also possible. 

Thottathil, J.K., Ryono, D.E., Przybyla, C.A., Moniot, J.L., and Neubeck, R., Preparation of phosphinic acids Michael addition of phosphorous acids/esters to conjugated systems, Tetrahedron Lett., 4741,1984. 

Depending on the substituents, different product distributions of phos-phonic 36d-f and phosphoric acid esters 33d-f have been found in the reaction of HFA and phosphinic acid esters (752). 

S.D. Alexandratos, M.A. Strand, D.R. Quillen and A.J. Walder, Synthesis and characteristics of bifunctional phosphinic acid resins, Macromolecules, 1985, 18, 829 R.H. Selzer and D.G. Howery, Phosphoric acid ester cation-exchange resins. 1. Synthesis and preliminary characterization, Macromolecules, 1986, 19, 2673 Phos-phonic acid ester cation-exchange resins. 2. Physicochemical characterization, ibid. 1986, 19, 2974. 

The phosphobetaines can be prepared by the reaction of alkyldimethylamine with bromoalkylethylphenyl-phosphinate or bromoalkyidiethylphosphonate. The phosphorus reagents are prepared from diethylphenyl-phosphonite or triethylphosphite and a dibromalkane by an Arbusov reaction (27). Alternatively, phosphobetaines can be prepared by the reaction of an alkylamido-propyldimethylamine with a phosphoric acid ester and formaldehyde (28). 

Phosphorous Compound The phosphorous compoimd that can be used as fire retardant include a phosphoric acid ester compoimd, a phosphoamidate compound, an oxaphospholane compound, a carboxy phosphinic acid, phosphoric acid ester morpholide compound and a phosphazene compound. The phosphorous compounds are used alone or in combination. The phosphorous compound may be used in the amount of about 0.1 to 50 parts by weight based on 100 parts by weight of the base resin. The phosphorous compounds are described in detail as follows. 

Thio) phosphoric acid ester (Thio) phosphonic (fhio) phosphinic acid ester acid ester Sulfonic acid ester Sulfonic acid amide... 

Acryhc esters dimerize to give the 2-methylene glutaric acid esters catalyzed by tertiary organic phosphines (37) or organic phosphorous triamides, phosphonous diamides, or phosphinous amides (38). Yields of 75—80% dimer, together with 15—20% trimer, are obtained. Reaction conditions can be varied to obtain high yields of trimer, tetramer, and other polymers. 

When a phosphite is used as a catalyst modifier, it is susceptible to oxidation in the same manner as a phosphine. Unlike triphenylphosphine oxide, which is relatively innocuous except for precipitation when the solubility limit is reached, phosphite oxidation products may hydrolyze to give phosphoric acid. Since phosphites are esters, phosphoric acid can catalyst additional hydrolysis. Other than limiting formation of phosphite oxidation products, the best approach is to include some acidity control technology in the separation or reaction system. 

Alkyl esters of phosphoric acid and phosphine oxides will extract metals and mineral acids by direct solvation. Tri-//-butyl phosphate (TBP) and tri- -octyl phosphine oxide (TOPO)... 

Chloroform, Chloropicrin, 1,1-Dichloroethylene, Endrin, Hexachlorocyclopentadiene, Methyl chloride. Methylene chloride, Tetrachloroethylene, 1,1,1 -Trichloroethane, Trichloroethylene Phosphine, see Pentachlorobenzene, Phorate Phosphoric acid, see Dichlorvos, Ethephon. Glvphosate. Malathion, Mevinphos, Parathion, Sulfotepp, Tributyl phosphate, Trichlorfon Phosphoric acid, dimethyl ester, see Mevinphos, Oxvdemeton-methvl Phosphorothioic acid, see Parathion Photoaldrin, see Aldrin Photoaldrin chlorohydrin, see Dieldrin Photodieldrin, see Aldrin, Dieldrin Photoheptachlor, see Heptachlor Photoketoaldrin, see Aldrin Phthalaldehyde, see Naphthalene Phthalaldehydes, see Tolnene Phthalic acid, see Anthracene, Benzo[a]anthracene, Benzyl bntyl phthalate, Dichlone. Diethyl phthalate, Dimethyl phthalate, Naphthalene, Naptalam. I ene... 

Ethyl dichlorophosphite is a colorless liquid, with an irritating odor. It fumes when exposed to air. It has the following physical constants sp. gr., 1.30526 b.p., 117.5° n °, 1.47176. It decomposes at 165° to ethyl chloride, phosphorus, phosphine, and phosphoric acid.3 It reacts with water to form hydrogen chloride and phosphorous acid, and with alcohols to form esters. When ammonia is passed through ethyl dichlorophosphite, ethyl phospheni-midate (ethoxyphosphimide), C2H5OP=NH, is formed. 

Considerable interest has been directed to the preparation of cellulose phosphates because of their flame retarding properties and potential use in textiles. Phosphorylation can be accomplished in several ways, e.g., by heating cellulose at high temperatures with molten urea and phosphoric acid. Other phosphor-containing esters of cellulose include phosphites, phosphinates, and phosphonites. In addition, boric acid esters have been prepared. 

The unsaturated character of these trialkyl esters was shown by the ease with which they were attacked by nitric acid, but still more clearly by the formation, with evolution of heat, of stable crystalline addition compounds when they were mixed with cuprous halides. Thus CuC1.P(OC2H5)3 was described as consisting of colourless crystals melting at 190° to 192° C. and soluble in organic solvents.4 This property they share with phosphine, alkylphosphines and phosphorus trihalides. The phosphoric esters were quite indifferent to cuprous halides. Nor were such addition compounds formed either by phosphorous acid itself or by the dialkyl esters, which may show that the latter compounds have the unsymmetrical formula. Phosphorous acid probably exists in both forms, but first as P(OH)3, i.e. when produced from PC13 and Ha0.5 This may be transformed into the unsym-metrieal form through an addition compound HC1.P(0H)3,4 and probably also exists in the form of complex molecules, such as... 

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