Polymerised Phosphine Oxides

Polymerised phosphine oxides are generally much more stable than polymerised phosphines. A high-molecular-weight polymer can be obtained from diphenyl(vinyl)phosphine oxide using either free radical or anionic initiation (12.176). 

The oxidative polymerisation of unsaturated phosphines (12.177), the reaction of dibutyl hydrogen phosphate with pentamethylene MgBrj (12.178) and reactions (12.179) and (12.180) all lead to phosphine oxide-type polymers. 

Polymeric tertiary phosphine oxides can be obtained by heating methylphosphonous dihalides with saturated hydrocarbons (12.181). Other methods utilise condensations of types (12.182) and (12.183). 

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Phosphine-derivatised poly(4-/i r/-butylstyrene) has been prepared for use as a soluble support in homogeneous catalysis.It was used in a monophasic medium and separation of the catalysts after reaction was effected either by cooling- or water-induced phase separation. The support was prepared by co-polymerisation of /i r/-butylstyrene with a phosphine oxide-containing styrene monomer (Scheme 19) A small quantity of a methyl red-labelled comonomer was also added to act as a colorometric tag to facilitate studies of the extent of separation and recycling of the polymeric material. The phosphine oxide was reduced to the free phosphine after the polymerisation step was complete. 

Organozincs generated under similar conditions have been shown to add to optically active vinyl phosphine oxides with retention of configuration at phosphorus [63] (Scheme 8). In this case a 1 1 zinc/copper couple was employed to activate the zinc. The one-pot reaction proceeded best with tertiary or secondary alkyl halides. The resulting phosphine oxides are used as chiral ligands for catalysts in asymmetric synthesis and were previously only available by reaction with the analogous cuprate [147] since conjugate addition of simple alkyl halides normally results in polymerisation. 

Catalytic forms of copper, mercury and silver acetylides, supported on alumina, carbon or silica and used for polymerisation of alkanes, are relatively stable [3], In contact with acetylene, silver and mercury salts will also give explosive acetylides, the mercury derivatives being complex [4], Many of the metal acetylides react violently with oxidants. Impact sensitivities of the dry copper derivatives of acetylene, buten-3-yne and l,3-hexadien-5-yne were determined as 2.4, 2.4 and 4.0 kg m, respectively. The copper derivative of a polyacetylene mixture generated by low-temperature polymerisation of acetylene detonated under 1.2 kg m impact. Sensitivities were much lower for the moist compounds [5], Explosive copper and silver derivatives give non-explosive complexes with trimethyl-, tributyl- or triphenyl-phosphine [6], Formation of silver acetylide on silver-containing solders needs higher acetylene and ammonia concentrations than for formation of copper acetylide. Acetylides are always formed on brass and copper or on silver-containing solders in an atmosphere of acetylene derived from calcium carbide (and which contains traces of phosphine). Silver acetylide is a more efficient explosion initiator than copper acetylide [7],... 

The previously accepted pathway consisted of P-H oxidative addition to Pt(0) to form 19 followed by coordination and insertion of the alkene in the Pt-P bond to form 20 and a final reductive elimination to furnish the product and regenerate the catalyst. Another possibility is the nucleophilic attack of phosphido complex 19 to the alkene ( Michael addition mechanism, as in anionic polymerisation) to generate the zwitterionic intermediate 21. This complex can yield the hydrophosphination product 11 via one of two complementary pathways. Carbanion attack at the cationic platinum hydride i.e. intramolecular hydrogen transfer) would yield the final phosphine complexed to Pt(0) that would be displaced by an equivalent of PHR R to furnish, after oxidative addition, starting complex 19. Alternatively, the anionic carbon atom in 21 could attack the platinum centre directly, forming the cyclic intermediate 22. From here Pt-P bond dissociation would generate 20, which would furnish the product after reductive elimination. 

TEMPO is widely used as a radical trap, as a structural probe for biological systems in conjunction with EPR spectroscopy, as a reagent in organic synthesis, and as a mediator in controlled free radical polymerisation. As well as alcohol oxidation, TEMPO also finds use in the oxidation of other functional groups, including amines, phosphines, phenols, anilines, sulfides and organometallic compounds [144]. 

A(a)<- by stereoelection the polymerization of the racemic monomer R,S) gives a predominant R oi S polymer polypropylene oxide polypropylene sulfide poly-a-aminoacid A -carboxylic acid anhydride (initiator, aluminum alkyl, Ni carboxylate phosphine). A(b) by stereoelection one enantiomer of racemic mixture polymerises more easily than the other one racemic a-olefin B Chromatography of poly-racemic RRS/SSR oiRR/SS) just some examples are known (not separation but more exactly enrichment)... 

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