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Acetylene, substituted polymerized

The acetylene substitution reaction proceeds much more rapidly than the related olefin reaction. The acetylene products and starting materials also undergo side reactions such as polymerization concurrently with the substitution. The best yields are obtained when the reactants are diluted with a large excess of amine, or carried out at lower temperatures in methanol with sodium methoxide as the base. Vinylacetylene derivatives can also be prepared by this reaction starting with vinylic halides. For example, ( )-methyl 3-bromo-2-methylpropenoate and r-butylacetylene react in 2 hours at 100° to form the expected vinylacetylene derivative in 59% yield ... [Pg.347]

In contrast to unsubstituted acetylene, the polymerization of differently substituted 1-alkynes and di-l-alkynes may be carried out conveniently using Schrock-type catalysts. Dipropargylmalonate and derivatives thereof may be cyclopolymer-ized in a living manner using Mo(N-2,6-i-Pr2-CgH3)(CH-t-Bu)[OCMe(CF3)2]2. The... [Pg.168]

Organometallic derivatives of metal carbonyls have been shown to be intermediates in the polymerization and cyclization of acetylenes in the presence of metal carbonyls, and many acetylene derivatives of metal carbonyl compounds have been isolated 43,198). Acetylene-substituted carbonyl clusters have, in general, been prepared by one of two methods. [Pg.491]

The examination of conjugated, soluble, substituted polyacetylenes remains in its early stages. There are still a number of interesting synthetic targets which have not been approached. One example is fluorinated polyacetylene. Theoretical reports indicate that the material should behave very differently from normal polyacetylene [143-147]. For example, a recent report suggests that poly(difluoroacetylene) will be nonplanar, and that poly(fluoro-acetylene), if polymerized head-to-tail, will be most stable in the cis configuration [148]. [Pg.376]

The polycondensation of acetylene-substituted metallocenes has yielded polymers containing backbone aUcyne bridges. The synthesis of l-iodo-2-methoxy-methyl-3-ethynylferreocene and l-iodo-2-(N,N-dimethylamino methyl)-3-ethynyl-ferreocene was reported by Plenio and coworkers. Polymerization of these ferrocene-based complexes gave rise to soluble bimodal 1,3-linked ferrocene-acetylene polymers. Polymers exhibiting optical activity or functionalized sidechains were produced via Sonogashira coupling reactions. [Pg.13]

It is now clearly demonstrated through the use of free radical traps that all organic liquids will undergo cavitation and generate bond homolysis, if the ambient temperature is sufficiently low (i.e., in order to reduce the solvent system s vapor pressure) (89,90,161,162). The sonolysis of alkanes is quite similar to very high temperature pyrolysis, yielding the products expected (H2, CH4, 1-alkenes, and acetylene) from the well-understood Rice radical chain mechanism (89). Other recent reports compare the sonolysis and pyrolysis of biacetyl (which gives primarily acetone) (163) and the sonolysis and radiolysis of menthone (164). Nonaqueous chemistry can be complex, however, as in the tarry polymerization of several substituted benzenes (165). [Pg.94]

The urethane-substituted polydiacetylenes exhibit thermo-chromic transition with low and high temperature crystal phases favoring acetylenic and butatriene backbone, respectively (4-6). Our interest in the application of epitaxial polymerization to diacetylenes has been the possibility of substrate control over orientation, structure, and the single crystal nature of thin films. [Pg.229]

The combination of these findings with the aforementioned results of Beckhaus, Rosenthal, and Mach may also be interpreted in terms of an alternative mechanism for the polymerization of acetylene, which differs from that of Alt [12] (Scheme 10.3). In the absence of coupling, as in 11, or of twofold C—H activation as found in 12, the steps after substitution of MeiSiC=CSiMci by HC=CH and formation of Cp2Ti(i]2-HC2H) are (i) oxidative addition to give the hydrido-acetylide Cp2Ti(H)(C=CH),... [Pg.361]

The electronic properties of germanium have led to an interest in incorporating the element into extended polymeric chains due to the intrinsic properties of the polymers themselves or in their use as precursors for material synth-esis. Catalytic co-polymerization of the germylene Ge[N(SiMe3)2]2 with various substituted acetylenes leads to... [Pg.766]

The assignment of the monomer solution spectrum was performed by using an NMR spectral database system (SDBS-NMR)54. The signals of the six acetylene carbons from 60.34 to 81.91 ppm in the solution spectrum indicated the monomer structure of a dodec-ahexyne derivative substituted symmetrically by alkyl groups. Since the spectral patterns in Figure 36A are almost the same as those of the monomer, only a small extent of polymerization had occurred during the 30 min after recrystallization. The signal at about... [Pg.142]

Poly (acetylenes) [16], There are several catalysts available for polymerization of substituted acetylenes. Whereas Ziegler-Natta catalysts are quite effective for polymerization of acetylene itself and simple alkylacetylenes, they are not active towards other substituted acetylenes, e.g. phenylacetylenes. Olefin-metathesis catalysts (Masuda, 1985 Masuda and Higashimura, 1984, 1986) and Rh(i) catalysts (Furlani et al., 1986 Tabata, 1987) are often employed. In our experience, however, many persistent radicals and typical nitrogen-containing functional groups serve as good poisons for these catalysts. Therefore, radical centres have to be introduced after construction of the polymer skeletons. Fortunately, the polymers obtained with these catalysts are often soluble in one or other organic solvent. For example, methyl p-ethynylbenzoate can be polymerized to a brick-coloured amorph- See the Appendix on p. 245 of suffixes to structural formula numbers. [Pg.220]

C yields a polymer with 90% cis content polymerization at 100°C yields a polymer with >90% trans content. Polyacetylene, doped with an oxidant or a reductant, showed promise as a polymeric semiconductor [Chien, 1984], That promise was not realized because of the oxidative instability of polyacetylene and emergence of cheaper and more stable polymer systems (Sec. 2-14j). Various substituted acetylenes such as phenylacetylene have also been studied [Kanki et al., 2002 Misumi et al., 2000],... [Pg.684]

This chapter surveys the polymerization of substituted acetylenes focusing on the research during this decade. Monomers and polymers, polymerization catalysts, controlled polymerizations, and functional polyacetylenes are discussed. Readers are encouraged to access other reviews and monographs on the polymerization of substituted acetylenes, and a,cj-diynes. ... [Pg.559]

As shown above, a number of transition metal catalysts for polymerization of acetylenic compounds have been reported, especially for substituted acetylenes. Here, typical catalysts are described first the other catalysts not mentioned in detail, but summarized in Table 8, are shown after the typical ones. [Pg.569]

Mo and W hexacarbonyls, Mo(CO)6 and W(CO)6, alone do not induce polymerization of acetylenic compounds. However, UV irradiation toward these catalysts in the presence of halogenated compounds can form active species for polymerization of various substituted acetylenes. Carbon tetrachloride, CCI4, when used as the solvent for the polymerization, plays a very important role for the formation of active species, and thus cannot be replaced by toluene that is often used for metal chloride-based catalysts. Although these metal carbonyl-type catalysts are less active compared to the metal halide-based counterparts, they can provide high MW polymers. It is a great advantage that the metal carbonyl catalysts are very stable under air and thus handling is much easier. [Pg.570]

Mo and W alkylidene complexes 4, the so-called Schrock carbenes, have explosively evolved the polymerization chemistry of substituted acetylenes. Although the preparation of these catalysts is relatively difficult because of their low stability, in other words, high reactivity, they elegantly act as living polymerization catalysts for substituted... [Pg.571]

Compared to early transition metals, the number of group 8-10 transition metal catalysts for the polymerization of substituted acetylenes has been relatively small except for Rh. However, unique aspects of these late transition metal catalysts have been revealed which cannot be seen in early transition metals and conventional Rh catalysts. [Pg.574]

Group 10 transition metal catalysts including Ni and Pd are known as a new class of catalysts for the polymerization of substituted acetylenes, but the reports treating these catalysts are still not many. Some of the reports in an early stage displayed that the group 10 catalysts rather induce cyclic and linear oligomerizations of acetylene monomers. Thus, only fragmental information is available in some of the papers. [Pg.574]

See other pages where Acetylene, substituted polymerized is mentioned: [Pg.187]    [Pg.10]    [Pg.62]    [Pg.13]    [Pg.154]    [Pg.169]    [Pg.232]    [Pg.234]    [Pg.236]    [Pg.241]    [Pg.242]    [Pg.228]    [Pg.31]    [Pg.130]    [Pg.14]    [Pg.102]    [Pg.558]    [Pg.566]    [Pg.566]    [Pg.568]    [Pg.569]    [Pg.570]    [Pg.571]    [Pg.571]    [Pg.573]    [Pg.574]    [Pg.574]    [Pg.574]   
See also in sourсe #XX -- [ Pg.388 , Pg.391 , Pg.392 ]



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