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Ethylene oxide, dimethyl

Poly(ethylene oxide)-poly(butylene terephthalate) multiblock copolymer Poly(ethylene oxide-6-propylene fumarate-6-ethylene oxide) Poly(ethylene oxide-6-propylene fumarate-6-ethylene oxide) dimethyl ether... [Pg.476]

Poly(ethylene oxide-i-propylene fumarate-Z>-ethylene oxide) dimethyl ether... [Pg.502]

Poly[(ethylene oxide)-h/oc -(propylene fumarate)-h/oc -(ethylene oxide)] dimethyl ether 841301-92-6... [Pg.85]

Figure 24 Relative concentration of (a) free anions, (b) ion pairs, and (c) aggregates in three different electrolyte polymers containing lithium triflate, plotted against the molal concentration of the electrolyte. Poly (propylene glycol) methyl-terminated, PPG-CHg o poly (propylene glycol) OH-terminated, PPG-OH A poly(ethylene oxide) dimethyl ether, PEODME. (Adapted from Refs. 369, 372, and 374.)... Figure 24 Relative concentration of (a) free anions, (b) ion pairs, and (c) aggregates in three different electrolyte polymers containing lithium triflate, plotted against the molal concentration of the electrolyte. Poly (propylene glycol) methyl-terminated, PPG-CHg o poly (propylene glycol) OH-terminated, PPG-OH A poly(ethylene oxide) dimethyl ether, PEODME. (Adapted from Refs. 369, 372, and 374.)...
YAN Yang, J., Wegner, G., and Koningsveld, R., Phase behavior of ethylene oxide-dimethyl-siloxane PEO-PDMS-PEO triblock copolymers with water. Colloid Polym. Sci., 270, 1080,... [Pg.192]

FERRY A, ORADD G and JACOBSSON p, A Raman, ac impedance and pfg-NMR investigation of poly(ethylene oxide) dimethyl ether (400) complexed with LiCFjSOs , Electrochim Acta, 1998,43(10-11), 1471-1476... [Pg.215]

SUN J, MACFARLANE D R, FORSYTH M (1996), lon conductive poly(ethylene oxide-dimethyl siloxane) copolymers , J Polym Sci Part A, 34,3465-3470. [Pg.276]

View molecular models of dimethyl ether and ethylene oxide on Learning By Modeling Which one has the greater dipole moment Do the calculated dipole moments bear any relation ship to the observed boiling points (ethylene oxide +10°C dimethyl ether —25°C) d... [Pg.700]

Eyrol 51 is a water-soluble Hquid containing about 21% phosphoms. It is made by a multistep process from dimethyl methylphosphonate, phosphoms pentoxide, and ethylene oxide. The end groups are principally primary hydroxyl and the compound can thus be incorporated chemically into aminoplasts, phenoHc resins, and polyurethanes. Eyrol 51, or 58 if diluted with a small amount of isopropanol, is used along with amino resins to produce a flame-retardant resin finish on paper used for automotive air filters, or for backcoating of upholstery fabric to pass the British or California flammabiHty standards. [Pg.479]

Fats, Oils, or Fatty Acids. The primary products produced direcdy from fats, oils, or fatty acids without a nitrile iatermediate are the quatemized amidoamines, imidazolines, and ethoxylated derivatives (Fig. 3). Reaction of fatty acids or tallow with various polyamines produces the iatermediate dialkylarnidoarnine. By controlling reaction conditions, dehydration can be continued until the imidazoline is produced. Quaternaries are produced from both amidoamines and imidazolines by reaction with methyl chloride or dimethyl sulfate. The amidoamines can also react with ethylene oxide (qv) to produce ethoxylated amidoamines which are then quaternized. [Pg.381]

Dimethyl sulfoxide can also be used as a reaction solvent for other polymerizations. Ethylene oxide is rapidly and completely polymerized in DMSO (85). Diisocyanates and polyols or polyamines dissolve and react in DMSO to form solutions of polyurethanes (86) (see Solvents, industrial). [Pg.112]

Several cleaning formulations for specific uses contain unreacted polyamines. Examples include mixtures of ammonium alkylbenzenesulfonate, solvents, and PIP which give good cleaning and shine performance on mirrors and other hard surfaces without rinsing (305), and a hard-surface cleaner composed of a water-soluble vinyl acetate—vinyl alcohol copolymer, EDA, cyclohexanone [108-94-1] dimethyl sulfoxide [67-68-5] a surfactant, and water (306). TEPA, to which an average of 17 moles of ethylene oxide are added, improves the clay sod removal and sod antiredeposition properties of certain hquid laundry detergents (307). [Pg.48]

Other polyamine derivatives are used to break the oil/water emulsions produced at times by petroleum wells. Materials such as polyether polyols prepared by reaction of EDA with propylene and ethylene oxides (309) the products derived from various ethyleneamines reacting with isocyanate-capped polyols and quaternized with dimethyl sulfate (310) and mixtures of PEHA with oxyalkylated alkylphenol—formaldehyde resins (311) have been used. [Pg.48]

Little l-//-pentafluoropropylene is produced anymore, because its existence IS no longer justified as a less stable alternative to HFP m VDF-based elastomers, given the expiration of patents covenng the basic VDF/HFP/(TFE) compositions Perfluoro-1,1-dimethyl dioxole is prepared from hexafluoroacetone and ethylene oxide in four propnetary steps [5] (equation 4)... [Pg.1104]

By 0-acylation with 2-methyl-1,3-dioxolenium fluoroborate, which reacts as 0-acetyl ethylene oxide, 2,6-dimethyl-4-pyroiie is converted into 4-acetoxy-2,0-dimethylpyrylium fluoroborate (24, Y = 0, R = Ac, X=BT 4). The alleged compound with this structure which has been obtained from 8 and acetyl fluoroborate is, in fact, the BF3-complex of the pyrone. [Pg.257]

Grainger DW, Kim SW, and Feijen J. Poly(dimethyl siloxane)-poly(ethylene oxide)-heparin block copolymers. I Synthesis and characterization. J Biomed Mater Res, 1988, 22, 231-242. [Pg.254]

Beryllium and certain compounds Cadmium and certain compounds Carbon tetrachloride Chlorambucil Cyclophosphamide Dimethylcarbamoyl chloride Dimethyl sulphate Ethylene oxide Iron dextran... [Pg.46]

DMC and EG were main products of the transesterification reaction. No by-product such as dimethyl ether and glycol monoethyl ether was observed in the resulting products. Only small peaks of ethylene oxide from the decomposition of EC could be detected at longer reaction time and at high temperature. [Pg.330]

Materials and Purification. Chemicals were purchased from Aldrich chemical company and used as received unless otherwise noted 1,1,1,3,3,3-hexamethyl disilazane, ethylene glycol, triphosgene, poly(ethylene oxide) (MW = 600), poly(tetramethylene oxide) (MW = 1000), poly(caprolactonediol) (MW = 530), toluene diisocyanate (TDI), anhydrous ethanol (Barker Analyzed), L-lysine monohydride (Sigma) and methylene bis-4-phenyl isocyanate (MDI) (Kodak). Ethyl ether (Barker Analyzer), triethylamine and dimethyl acetamide were respectively dried with sodium, calcium hydride and barium oxide overnight, and then distilled. Thionyl chloride and diethylphosphite were distilled before use. [Pg.142]

In selective etherification, it is important to distinguish between reversible and irreversible reactions. The former class comprises etherifications with dimethyl sulfate, halogen compounds, oxirane (ethylene oxide), and diazoalkanes, whereas the latter class involves addition reactions of the Michael type of hydroxyl groups to activated alkenes. In this Section, irreversible and reversible reactions are described separately, and a further distinction is made in the former group by placing the rather specialized, diazoalkane-based alkylations in a separate subsection. [Pg.51]

Scheme 8.13 and Eqs. 8.6-8.10 reveal that lithiated methoxyallene 42 is sufficiently reactive towards a variety of electrophiles such as alkyl halides [44, 45], ethylene oxide [12c], tosylated aziridine 45 [46], dimethyl disulfide [12b], trialkylstannyl and trialkylsilyl chlorides [47, 48] and iodine [49]. These substitution reactions proceed with excellent regioselectivity and the corresponding a-functionalized products are obtained in good to high yields. An exceptional case was found by treatment of 42 with a guanidinium salt, which led to a 60 40 mixture of a- and y-adducts 50 and 51 (Eq. 8.11) [50],... [Pg.432]

An amorphous material sometimes referred to as amorphous poly(ethylene oxide), aPEO, consists of medium but randomly-variable length segments of poly(ethylene oxide) joined by methyleneoxide units. Fig. 5.13 (Wilson, Nicholas, Mobbs, Booth and Giles, 1990). These methyleneoxide units break up the regular helical pattern of poly(ethylene oxide) and in doing so suppress crystallisation. The aPEO host polymer and its salt complexes can crystallise below room temperature, but this is not detrimental to the properties of the polymer-salt complexes at or above room temperature. Similarly, dimethyl siloxy units have been introduced between medium length poly(ethylene oxide) units to produce an amorphous polymer. Fig. 5.14 (Nagoka, Naruse, Shinohara and Watanabe, 1984). [Pg.107]

Fig. 5.14 Dimethyl siloxy linked poly(ethylene oxide). Fig. 5.14 Dimethyl siloxy linked poly(ethylene oxide).
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See also in sourсe #XX -- [ Pg.328 , Pg.329 ]



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