Phosphonate Phosphonium halides

In contrast to stabilizers, fire retardants must be added in much higher concentrations, which affect thermal and mechanical properties as well as cost. Sherr and co-workers report that novel derivatives of phosphine oxides, phosphonic acids, phosphinic acid, and phosphonium halides may be used generally in concentrations as low as 2.5-5 p.p.h. to be effective fire retardants in polyethylene and poly (methyl methacrylate). 

Mono- and diphosphonium halides have been found to be flame retardants for plastic materials. Their effectiveness can be related to the formation of various active phosphorus compounds, as well as to many of the postulated mechanisms for flame retardant action. The compounds are postulated to be effective because they decompose on ignition to thermally stable phosphine oxides or phosphonic acids which, in turn, are decomposed to continuous films of phosphate glass. In addition, the phosphonium halides form alkyl halides which cool the flame and/or form halogen acids which are fame retardants. 

Tn the preceding chapter (19) we described the use of phosphine A oxides, phosphonic acids, and phosphinic acids as flame retardants for thermoplastic materials. We also have found phosphonium halides to be effective flame retardants for plastics (5, 6). These compounds were either the monophosphonium halides,... 

Although other mechanisms are conceivable, the most likely scheme involves direct nucleophilic displacement by phosphite on carbon to furnish a trialkoxy phosphonium halide intermediate as in the Michaehs-Arbuzov reaction. Recently, we have developed an improved method for the preparation of Mannich bases of steroids and carried ouf reactions with their methiodides and trialkyl phosphite to obtain the first steroidal phosphonates to be reported (132). 

Cyclopropanes are formed in the condensation of epoxides with ylides derived from phosphonates. Attempts to carry out similar reactions with phosphonium ylides were generally unsuccessful, an exception being the reaction of the phosphonium halide (25) with oxiran. ... 

Dielectric relaxation studies of phosphorylated polyethers from — 180° to 200 °C have been used to study their structures. The magnitude of the dielectric constants of high-phosphonic-acid-content polymers is much larger than predicted, which suggests a microphase-separated structure. Conductance studies on some aryl- and alkyl-phosphonium salts showed a higher conductance for the halides than for the nitrate. ... 

This variation of the Wittig reaction uses ylides prepared from phosphonates.12 The Horner-Wadsworth-Emmons method has several advantages over the use of phosphoranes. These ylides are more reactive than the corresponding phosphoranes, especially when substituted with an electron withdrawing group. In addition the phosphorus product is a phosphate ester and soluble in water - unlike the Ph3PO product of the Wittig reaction - which makes it easy to separate from the olefin product. Phosphonates are also cheaper than phosphonium salts and can easily be prepared by the Arbuzov reaction from phosphanes and halides. 

The Michaelis-Arbuzov reaction is the most used and well-known method for the synthesis of phosphonates and their derivatives and may also be used to synthesize phosphinates and tertiary phosphine oxides. The simplest form of the Michaelis-Arbuzov reaction is the reaction of a trialkyl phosphite, 3, with an alkyl halide, 4, to yield a dialkyl alkylphosphonate, 6, and new alkyl halide, 7 (Scheme 2). During this transformation the phosphorus atom of a ter-valent phosphorus(III) species (3) acts as a nucleophile resulting in the formation of an intermediate alkoxy phosphonium salt 5, containing a new [P—C] bond. The precise structure of the intermediates 5 is a subject of debate—as reflected by common reference to them as pseudophosphonium salts —with a penta-coordinate species (containing a [P—X] bond) being proposed and detected in some cases.18 Decomposition (usually rapid under the reaction conditions) of the intermediate 5 by nucleophilic attack of X- on one of the alkyl groups R1, with concomitant formation of a [1 =0] bond yields the product pentavalent phosphorus(V) compound (6) and the new alkyl halide, 7. 

AUcoxyaminophosphines react with alkyl halides in an Arbuzov Michaelis type reaction to form phosphonic acid diamides via thermally unstable phosphonium intermediates (equation 5). ... 

The first step of the mechanism is the nucleophilic attack (Sn2) of the alkyl halide by the phosphorous to form a phosphonium salt A. Under the reaction conditions (heat) the phosphonium salt A is unstable and undergoes a C-0 bond cleavage (the halide ion (X ) acts as a nucleophile and attacks one of the alkyl groups in an Sn2 reaction) to afford the phosphonate ester. 

Trialkyl phosphites undergo the Michaelis-Arbusov reaction with alkyl halides to give dialkyl phosphonates the initial phosphonium ion is attacked at one the alkyl groups by the newly liberated halide. The reaction is useful in producing non-fissile but isosteric analogues of activated sugars for mechanistic studies (Figure 6.51). ... 

Thus, with model substrates, we initially explored both the acylation of (3) and (4). Both ylides readily underwent acylation with acyl halides or acetic anhydride to give the C-acylated phosphonate or phosphonium salt... 

Methyleneaminophosphines (10), on treatment with methyl iodide, give the expected phosphonium salts (11), which on thermolysis undergo a reaction analogous to the Arbusov reaction to give imidophosphoranes. Various phosphonates and phosphine oxides have been prepared by the reaction of the anions (RO)aP—0 Na+ and R2P—0 Na+ with alkyl halides. The analogous reactions of the chlorohydrin (12) with sodium diethyl phosphonate give the cyclic phosphonate (13) as a mixture of geometrical isomers of approximately equal stability. ... 

The reaction of trialkylphosphines, especially triphenylphosphine, with alkyl halides is particularly useful since the resultant phosphonium salts are easily converted to the phosphonium ylid on treatment with a suitable base (sec. 8.8r kk Ylids are, of course, the reactive species in the well-known Wittig olefination reaction, which will be discussed in section 8.8.A.i. A related Sn2 process involves reaction of a trialkylphosphite with an alkyl halide, the Arbuzov reaction (sometimes called the Michaelis-Arbuzov reaction). Triethylphos-phite (70) reacts with iodomethane to give the phosphonium salt, 71. Heating generates the monoalkyl phos-phonic ester (72). This type of phosphonic ester can be converted to an ylid and used in the well-known Horner-Wadsworth-Emmons oiefination (sec. 8.8.A.iii). 

Among the other developed approaches to novel P-ylides, the synthesis of a-sulfanyl-a-phosphonyl phosphonium ylides (58) in quantitative yields via the addition of two equivalents of trialkylphosphites to phosphonodithio-formates should be mentioned. The subsequent reaction of these ylides with alkyl or benzyl halides gives stabilized sulfonium ylides (59) while their heating (18-150 h, 110 °C) leads to a-sulfanyl methylene bis-phosphonates through protonation-dealkylation intramolecular reactions. The synthesis... 

Fluorophosphoranes can be obtained from phosphonous and phosphinous halides by reactions with arsenic or antimony obtained with KHF2 (6.518). Some phosphinous halides react with sulphur compounds to give phosphinothioites (9.420), with phenyl azide to give monophosphazenes (7.447), and with ylids fluorides (6.504, 6.505). Hydrofluorophosphoranes produces phosphonium salts (6.377). Phosphonous and phosphinous halides can be condensed to form polyphosphines or cyclic derivatives (6.660, 6.666,6.680,6.684), or reacted to give P-P linkages (6.737). 

Amino-substituted (quasi-phosphonium) derivatives are produced in reaction (6.373) and by reaction of tertiary phosphines with chloramine or hydrazoic acid (6.104,6.105), or by the reaction of phosphonous diamides with chloramine or alkali metal halides (7.196). 

Phosphonium salts can be obtained by reacting phosphonous or phosphinous amides with chloramine or alkyl halides (7.196). Phosphonium salts containing both P-N and P-C linkages may also be made by the reaction of ammonia with pentaphosphoranes (7.197), and several other reactions (7.18), (7.468) through (7.470) and (6.375). 

A very useful modification of the Wittig reaction involves the reaction of phosphonate-stabilized carbanions with aldehydes or ketones, which is known as the Homer-Wadsworth-Emmons (HWE) reaction [7, 151,152], This reaction was originally described by Homer et al. [153, 154] and further defined by Wadsworth and Emmons [155]. Phosphonate-stabilized carbanions are more nucleophilic and more basic than phosphonium ylides. They are prepared by the addition of suitable bases to the corresponding alkylphosphonates, which are readily accessible through the Michaelis-Arbuzov reaction of trialkyl phosphites with alkyl halides (usually a-halo carbonyl compounds) [143]. In contrast to the Wittig reaction, the HWE reaction yields phosphate salt byproducts that are water-soluble and hence are readily separated from the desired alkene products by simple extraction. 

F-Methylation. Phosphonium salts are prepared by the quat-ernization of phosphines with methyl iodide. The displacement reaction is usually conducted in polar solvents such as acetonitrile or DMF. Dialkyl phosphonates are prepared from the reaction of trialkyl phosphites with alkyl halides, commonly known as the Arbuzov reaction. For example, diisopropyl methylphosphonate is prepared by heating a mixture of methyl iodide and Triisopropyl Phosphite (eq 34). ... 

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