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Poly substituents

This equation is an elaboration of the dual substituent-parameter (DSP) equation. Its development has been relatively recent, but Taft and Topsom, who have been closely associated with it, have already written a long review article151 involving the equation, and this article will probably acquire the status in respect of the PSP equation that the article of Ehrenson, Brownlee and Taft92 has in connection with the DSP equation. The name Poly Substituent-Parameter Equation was devised by the present author in a short... [Pg.522]

DSP = dual substituent-parameter EH = extended Hammett LDR = localized delocalized response PSP = poly substituent-parameter SSAR = substituent solvation assisted resonance. [Pg.1487]

Poly (dimethyl siloxane) offers the least steric hindrance of the polymers listed every other atom along the backbone of the chain is devoid of substituents in this case. [Pg.62]

The melting points of a series of poly(a-olefin) crystals were studied. All of the polymers were isotactic and had chain substituents of different bulkinesses. Table 4.2 lists some results. Use Eq. (4.5) as the basis for interpreting the trends in these data. [Pg.209]

Table 4.2 Values of T j, for Poly(a-olefin) Crystals in Which the Polymer has the Indicated Substituent (Results are Discussed in Example 4.1)... Table 4.2 Values of T j, for Poly(a-olefin) Crystals in Which the Polymer has the Indicated Substituent (Results are Discussed in Example 4.1)...
The presence of carbon—fluorine bonds in organic polymers is known to characteristically impart polymer stabiUty and solvent resistance. The poly(fluorosibcones) are siloxane polymers with fluorinated organic substituents bonded to siUcon. Poly(fluorosibcones) have unique appHcations resulting from the combination provided by fluorine substitution into a siloxane polymer stmcture (see Silicon compounds, silicones). [Pg.399]

Surface Protection. The surface properties of fluorosihcones have been studied over a number of years. The CF group has the lowest known intermolecular force of polymer substituents. A study (6) of liquid and solid forms of fluorosihcones has included a comparison to fluorocarbon polymers. The low surface tensions for poly(3,3,3-trifluoropropyl)methylsiloxane and poly(3,3,4,4,5,5,6,6,6-nonafluorohexyl)methylsiloxane both resemble some of the lowest tensions for fluorocarbon polymers, eg, polytetrafluoroethylene. [Pg.400]

Applications. Among the P—O- and P—N-substituted polymers, the fluoroalkoxy- and aryloxy-substituted polymers have so far shown the greatest commercial promise (14—16). Both poly[bis(2,2,2-trifluoroethoxy)phosphazene] [27290-40-0] and poly(diphenoxyphosphazene) [28212-48-8] are microcrystalline, thermoplastic polymers. However, when the substituent symmetry is dismpted with a randomly placed second substituent of different length, the polymers become amorphous and serve as good elastomers. Following initial development of the fluorophosphazene elastomers by the Firestone Tire and Rubber Co., both the fluoroalkoxy (EYPEL-F) and aryloxy (EYPEL-A) elastomers were manufactured by the Ethyl Corp. in the United States from the mid-1980s until 1993 (see ELASTOLffiRS,SYNTHETic-PHOSPHAZENEs). [Pg.257]

Applications. Polymers with small alkyl substituents, particularly (13), are ideal candidates for elastomer formulation because of quite low temperature flexibiUty, hydrolytic and chemical stabiUty, and high temperature stabiUty. The abiUty to readily incorporate other substituents (ia addition to methyl), particularly vinyl groups, should provide for conventional cure sites. In light of the biocompatibiUty of polysdoxanes and P—O- and P—N-substituted polyphosphazenes, poly(alkyl/arylphosphazenes) are also likely to be biocompatible polymers. Therefore, biomedical appHcations can also be envisaged for (3). A third potential appHcation is ia the area of soHd-state batteries. The first steps toward ionic conductivity have been observed with polymers (13) and (15) using lithium and silver salts (78). [Pg.260]

The synthesis of a new class of inorganic polymers (21) with a backbone consisting of alternating sulfur(VI) and nitrogen atoms, and with variable alkyl or aryl substituents as well as a fixed oxygen substituent on sulfur, has recentiy been accompHshed (83—85). These polymers are stmcturaHy analogous to poly(alk5l/arylphosphazenes). [Pg.261]

Many newer poly(phenylene oxide)s have been reported ia the early 1990s. Eor example, a number of poly(2,6-diphenyl-l,4-phenylene oxide)s were prepared with substituents ia the 4-positions of the pendent phenyl groups. Of particular iaterest is the 4-fluoro substitueat, which imparts a lower melting poiat, enhanced solubiUty, and a lesser tendency to crystallize than has been found for the parent material (1). [Pg.326]

These products are characterized in terms of moles of substitution (MS) rather than DS. MS is used because the reaction of an ethylene oxide or propylene oxide molecule with ceUulose leads to the formation of a new hydroxyl group with which another alkylene oxide molecule can react to form an oligomeric side chain. Therefore, theoreticaUy, there is no limit to the moles of substituent that can be added to each D-glucopyranosyl unit. MS denotes the average number of moles of alkylene oxide that has reacted per D-glucopyranosyl unit. Because starch is usuaUy derivatized to a considerably lesser degree than is ceUulose, formation of substituent poly(alkylene oxide) chains does not usuaUy occur when starch is hydroxyalkylated and DS = MS. [Pg.489]

Nearly all uses and appHcations of benzyl chloride are related to reactions of the active haUde substituent. More than two-thirds of benzyl chloride produced is used in the manufacture of benzyl butyl-phthalate, a plasticizer used extensively in vinyl flooring and other flexible poly(vinyl chloride) uses such as food packaging. Other significant uses are the manufacture of benzyl alcohol [100-51-6] and of benzyl chloride-derived quaternary ammonium compounds, each of which consumes more than 10% of the benzyl chloride produced. Smaller volume uses include the manufacture of benzyl cyanide [140-29-4], benzyl esters such as benzyl acetate [140-11-4], butyrate, cinnamate, and saUcylate, benzylamine [100-46-9], and benzyl dimethyl amine [103-83-8], and -benzylphenol [101-53-1]. In the dye industry benzyl chloride is used as an intermediate in the manufacture of triphenylmethane dyes (qv). First generation derivatives of benzyl chloride are processed further to pharmaceutical, perfume, and flavor products. [Pg.61]

Poly(hydroxyethyl methacrylate)-dye copolymers —The color additives formed by reaction of one or more of the foUowiag reactive dyes with poly(hydroxyethyl methacrylate), so that the sulfate group (or groups) or chlorine substituent of the dye is replaced by an ether linkage to poly(hydroxyethyl methacrylate) (see Dyes, reactive). The dyes that may be used alone or ia combination are... [Pg.453]

Polythiophenes with substituents other than alkyl groups at the 3 position have been prepared by the polymerization of substituted monomers. Many of these polymers have been substituted alkylthiophenes (8) where example side chains are (R =) —(86—89), —OCH (68), —NHC(0) (CH2) qCH (6 )) —0502(0112)30112 (90). Ohiral side chains have also been employed (91,92). Poly(3-alkoxythiophenes) (9) (93—95) and... [Pg.37]

See other pages where Poly substituents is mentioned: [Pg.480]    [Pg.522]    [Pg.94]    [Pg.120]    [Pg.232]    [Pg.277]    [Pg.480]    [Pg.522]    [Pg.1493]    [Pg.480]    [Pg.522]    [Pg.94]    [Pg.120]    [Pg.232]    [Pg.277]    [Pg.480]    [Pg.522]    [Pg.1493]    [Pg.184]    [Pg.240]    [Pg.16]    [Pg.486]    [Pg.317]    [Pg.258]    [Pg.259]    [Pg.262]    [Pg.409]    [Pg.328]    [Pg.398]    [Pg.171]    [Pg.171]    [Pg.502]    [Pg.65]    [Pg.586]    [Pg.289]    [Pg.210]    [Pg.232]    [Pg.285]    [Pg.307]   
See also in sourсe #XX -- [ Pg.32 , Pg.33 ]



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