Phosphine dehydration

Hydroxyall l Hydroperoxyall l Peroxides. There is evidence that hydroxyalkyl hydroperoxyalkyl peroxides (2, X = OH, Y = OOH) exist in equihbrium with their corresponding carbonyl compounds and other a-oxygen-substituted peroxides. For example, reaction with acyl haUdes yields diperoxyesters. Dilute acid hydrolysis yields the corresponding ketone (44). Reduction with phosphines yields di(hydroxyalkyl) peroxides and dehydration results in formation of cycHc diperoxides (4). 

The dimer of phosphonic acid, diphosphonic acid [36465-90-4] (pyrophosphoms acid), H4P2O3, is formed by the reaction of phosphoms trichloride and phosphonic acid in the ratio of 1 5. It is also formed by the thermal decomposition of phosphonic acid. Unlike the chemistry of phosphoric acid, thermal dehydration does not lead to polymers beyond the dimer extended dehydration leads to a disproportionation to condensed forms of phosphoric acid, such as [2466-09-3] and phosphine. 

Phosphine(s), chirality of, 314 Phosphite, DNA synthesis and, 1115 oxidation of, 1116 Phospholipid, 1066-1067 classification of, 1066 Phosphopantetheine, coenzyme A from. 817 structure of, 1127 Phosphoramidite, DNA synthesis and, 1115 Phosphoranc, 720 Phosphoric acid, pKa of, 51 Phosphoric acid anhydride, 1127 Phosphorus, hybridization of, 20 Phosphorus oxychloride, alcohol dehydration with. 620-622 Phosphorus tribromide, reaction with alcohols. 344. 618 Photochemical reaction, 1181 Photolithography, 505-506 resists for, 505-506 Photon, 419 energy- of. 420 Photosynthesis, 973-974 Phthalic acid, structure of, 753 Phthalimide, Gabriel amine synthesis and, 929... 

There is no way in which dehydration of alcohols can be used to prepare triple bonds gem-diols and vinylic alcohols are not normally stable compounds and vic-diols give either conjugated dienes or lose only 1 mol of water to give an aldehyde or ketone. Dienes can be prepared, however, by heating alkynyl alcohols with triphenyl phosphine. ... 

It is often said that the property of acidity is manifest only in the presence of a base, and NMR studies of probe molecules became common following studies of amines by Ellis [4] and Maciel [5, 6] and phosphines by Lunsford [7] in the early to mid 80s. More recently, the maturation of variable temperature MAS NMR has permitted the study of reactive probe molecules which are revealing not only in themselves but also in the intermediates and products that they form on the solid acid. We carried out detailed studies of aldol reactions in zeolites beginning with the early 1993 report of the synthesis of crotonaldehyde from acetaldehyde in HZSM-5 [8] and continuing through investigations of acetone, cyclopentanone [9] and propanal [10], The formation of mesityl oxide 1, from dimerization and dehydration of... 

With the phosphoric imidazolides D, E, and F, dehydration of the aldoximes can also be achieved (dioxane, room temperature, several hours). With diphenylimidazole-1-phosphonate (D) and phenyldiimidazole-l,l -phosphinate (E) the yields of nitriles are always higher than with (C6H50)2P(0)C1 and C6H50P(0)C12 however, with phosphoryl triimidazole (F) the yields are a little lower than with POCl3.[9] Spin-labeled phosphoric imidazolides of this type are also used for the dehydration of aldoximes.1103... 

Dehydration is undesirable because a, -unsaturated carbonyls are catalyst inhibitors. To make matters worse, phosphines can add to the a, -unsaturated carbonyl (Equation 2.3) to give a product that is a dehydration catalyst, so the deactivation spiral continues. 

In 1980, Gross and coworkers first applied this concept to a direct dehydrative glycosylation using tris(dimethylamino)phosphine and carbon tetrachloride [99]. 

Some homogeneous metal catalysts have been examined in the production of acrolein from glycerol [20], However, considering all reaction components present, it is more likely that soluble acids, such as HC1 and CF3SO3H, are responsible for glycerol dehydration instead of Pt and Pd phosphine complexes. 

A palladium phosphine complex [e.g., BCPE = l,2-bis(l,5-cyclooctylenephos-phino)ethane] was also reported to produce propanediols and n-propanol from glycerol at 443 K under 6 MPa CO/H2 atmosphere in acidic conditions, n-Propanol is the dominant product, while a slight preference for the formation of propane-1,3-diol is seen in the diol fraction. Reactions were performed at different temperatures in the range 413-448 K. Since acrolein was monitored at high temperature, a reaction network was proposed following a sequential dehydration/hydrogenation pathway [20]. 

Palladium-catalyzed a-arylation of ketones is performed with arylene dihalides and bifunctional aromatic ketones 148 to result in the bond formation at the r/) -a-carbon of the ketone, leading to polyketone 149. The reaction is carried out in the presence of Pd(0) and various phosphines. Several bidentate phosphines and bulky alkylphosphines such as dppf, BINAP, PCys, and P Bu3 are shown to be effective, while PPh3 results in no reaction. Arylene dibromide and diiodide are applicable as the co-monomers. The polymerization reaction is carried out in THE in the presence of NaO Bu at 75 °C under N2, and polymers 149 are isolated in 60-80% yields (M = 7000-15 000). Polyketone 149 is further transformed to conjugated polymer PPV by reduction of the ketone moiety with LiAlH4 followed by dehydration with an acid (Equation (69)). 

A more recent synthesis for (14-9) takes quite a different course. The first step comprises the displacement of one of the halogens in 1,4-dibromobenzene by the alkoxide from A-2-hydroxyethylpyrrolidine (15-2) in the presence of 18-crown ether to afford (15-3). Condensation of the lithium salt from (15-3) with 6-methoxy-tetralone (15-4) followed by dehydration of the initially formed carbinol give the intermediate (15-5), which incorporates the important basic ether. Reaction of that compound with pridinium bromide perbromide leads to the displacement of the vinylic proton by halogen and the formation of bromide (15-6). Condensation of that product with phenylboronic acid in the presence of a tetrakistriphenyl-phosphine palladium catalyst leads to the coupling of the phenyl group by the formal displacement of bromine. The product (14-9) is then taken on to lasoxifene (14-11) as above [16]. 

Nickel(II) complexes containing up to four molecules of trialkylphosphines have been prepared by the direct reaction of a nickel(II) salt with the appropriate phosphine in either aprotic or protic solvents. Anaerobic conditions have sometimes been employed in order to avoid oxidation of unstable phosphines whereas dimethoxypropane has occasionally been employed as a dehydrating agent when using hydrated nickel(II) salts. 

Neutral phosphates (RO)sPO, phosphonates (RO)2R PO and phosphinates (RO)R2PO are well known as extracting agents for metal ions.1823 The isolation of their metal complexes as crystalline compounds is, in general, more difficult than the preparation of complexes with other substituted phosphoryl compounds. It is often essential to reflux solutions of the reactants with dehydrating agents such as triethyl orthoformate or 2,2 -dimethoxypropane. In some cases the neutral phosphoryl ligands or triethyl orthoformate by themselves act as the reaction media in the synthesis of the nickel(II) complexes. 

A remarkable stereospecific dehydrative alkylation of (3-disulfones was reported by Falck et al. [406] under Mitsunobu conditions (triethyl phosphine, diethyl azodicarboxylate). The synthesis of a pheromone component of the lesser tea tortrix emphasizes some of the possibilities offered by coupling this reaction with further uses of the sulfone functionality. In the present case, monodesulfonylation with lithium naphthalenide (-78°C, 5 min), in situ alkylation (-78 to 23°C, 1 h), and Li-naphthalene cleavage of the second sulfonyl group (—78°C, 5 min) yielded in a one-pot procedure a THP ether which was converted into the sought after pheromone through direct acetylation. 

MITSUNOBU REACTION. Intcrnioleculur dehydration reaction occurring between alcohols and acidic components on treatment with diethyl azodtearboxylate and triphcnyl phosphine under mild neutral conditions. The reaction exhibits stereospecilicity and regional and functional selectivity. 

The most difficult impurity to eliminate is hydrogen, which is nearly always formed simultaneously with the phosphine. G. Ter-Gazarian found the most effective method of purifying the gas from traces of other hydrogen phosphides, and from hydrogen is repeated liquefaction and fractional distillation of the liquid. F. M. G. Johnson recommended alumina, dehydrated at a low temp., as a desiccating agent for the gas. 

Tetrakishydroxymethyl phosphonium chloride (THPC) is well established as a flame retardant agent with textiles (3). Collins (2) has suggested that THPC and urea break down to produce phosphoric acid via a phosphine oxide, phosphinic acid, and phosphonic acid. For cellulose, Collins concludes flameproofing is essentially caused by the dehydrating action of the phosphoric acid formed. 

The advantage of using a phosphine complex is that it contains no chloride, and the counter-ion is easily decomposed or eliminated. The complex has to be synthesised (not easy or cheap), and nonaqueous solutions are needed, which means that the support must be dehydrated, the solvent dried, and the finished catalyst stored in ampoules sealed under vacuum. 

Carbamoyl ylids, 101, however, could be dehydrated via 102 R = H using triphenyl-phosphine dibromide and triethylamine (154). This reaction leads to an interesting class of push-pull ynamine phosphonium salts 103 (154), 72). 

The final stages follow the mechanism of the Wittig reaction you met in Chapter 14 you see them as a special case of dehydration made favourable by the formation of a phosphine oxide as well as an unsaturated carbonyl compound. 

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