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The polymerization mechanism for the dual-side catalysts is totally different from the C2-symmetric complexes. Due to their geometry, the dual-side complexes show different stereoselectivities for monomer coordination and insertion. It was shown that the introduction of the stereoerror formation by the 5-substituted asymmetric catalysts originates predominately from the kinetic competition between chain back-skip and monomer coordination at the aspecific side of the catalyst [9],... [Pg.52]

Chien already postulated that C,-symmetric ansa-bridged complexes exist in two isomeric states, which interconvert during the course of the polymerization reaction [14, 15, 21, 22], Different stereoselectivities for monomer coordination and insertion are found for the two coordination sites of the asymmetric metallocene catalysts (Fig. 6,1 and IV). The migration of the polymer chain to the monomer, coordinated at the isoselective site f I—>11), followed by a consecutive chain back-skip (at higher temperatures) to the sterically less hindered side (II >111) leads to isotactic [mmmm] sequences [11],... [Pg.52]

By the time the concentration of monomer is low, the back-skip of the polymer chain to the less-hindered site is faster than the formation of the high-energy alkene coordinated intermediate (IV). For this reason, at low propene concentrations and elevated temperatures isotactic sequences are formed. The probability of monomer coordination at the aspecific site (IV) is enhanced when the propene concentration increases. The consequence is that single stereoerrors [mrrm] are introduced in the isotactic polymer chain. 13C-NMR was able to prove the mechanism because a... [Pg.52]

A special case of the chain back skip polymerization mechanism and therefore an entirely different polymerization behavior was observed for differently substituted asymmetric complexes (for example catalyst 3). Although asymmetric in structure, these catalysts follow the trend observed for C2-symmetric metallocenes [20], Chien et al. [23] reported a similar behavior for rac-[l-(9-r 5-fluorenyl)-2-(2,4,7-trimethyl-l-ri5-indenyl)ethane]zirconium dichloride and attributed this difference in the stereoerror formation to the fact that both sides of the catalyst are stereoselective thus isotactic polypropylene is obtained in the same manner as in the case of C2-symmetric metallocene catalysts. [Pg.53]

Fig. 7 Polypropylene stereoregularity versus polymerization temperature (catalyst 1 chain back-skip mechanism, catalyst 2 C2-symmetric-like mechanism) [11]... Fig. 7 Polypropylene stereoregularity versus polymerization temperature (catalyst 1 chain back-skip mechanism, catalyst 2 C2-symmetric-like mechanism) [11]...
Independent of the ligand system, two different activation methods have been used in performing the propylene polymerization experiments. In both cases, the catalytic activities and molecular weights of the polymers are a sensitive function of the aluminum content provided by the activators. This dependence suggested an additional reversible chain transfer to aluminum when activating with MAO. As lower contents of A1 are provided in the polymerization system in the case of in situ activation with TIBA/borate, the only mechanism occurring is the chain back-skip. Furthermore, the differences in the polymer microstructures prepared with MAO and borate as cocatalysts are reflected. They sustain the proposed reversible chain transfer. [Pg.61]

Scheme 1.3 Polymerization scheme showing the migratory insertion mechanism as well as the possible occurrence of the chain back-skip. The possible formation of agostic Mt-H bonds is... Scheme 1.3 Polymerization scheme showing the migratory insertion mechanism as well as the possible occurrence of the chain back-skip. The possible formation of agostic Mt-H bonds is...
Possible Back-Skip of Growing Chain. Several experimental facts relative to propene polymerization behavior of different metallocene-based catalytic systems can be rationalized by considering a disturbance of the chain migratory insertion mechanism due to a kinetic competition between the monomer coordination in the alkene-free state and a back-skip of the growing chain to the other possible coordination position (see Scheme 1.3). [Pg.25]

The possible occurrence of a back-skip of the chain for catalytic systems based on C2-symmetric metallocenes would not change the chirality of the transition state for the monomer insertion and hence would not influence the corresponding polymer stereostructure. On the contrary, for catalytic systems based on Cs-symmetric metallocenes, this phenomenon would invert the chirality of the transition state for the monomer insertion, and in fact it has been invoked to rationalize typical stereochemical defects (isolated m diads) in syndiotactic polypropylenes.9 376 60 This mechanism of formation of stereoerrors has been confirmed by their increase in polymerization runs conducted with reduced monomer concentrations.65 In fact, it is reasonable to expect an increase in the frequency of chain back-skip by reducing the monomer concentration and hence the frequency of monomer insertion. [Pg.25]

Note, in this connection, that it is incorrect to ascrise the formation of small amounts of syndiotactic polypropylene fraction in the presence of heterogeneous Ziegier-Natta catalysts to the operation of a mechanism assuming a lack of back skip of the chain in the last stage of insertion in the presence of these... [Pg.117]

The described chain migratory insertion mechanism, which operates in olefin polymerisation with metallocene-based single-site catalysts, follows that proposed by Cossee [268,277,278] for olefin polymerisation with heterogeneous catalysts there is, however, no back skip of the polymer chain to the previously occupied position prior to the coordination of the next monomer molecule, but rotation of the chain around the axis of the Mt-CH2 bond takes place (Figure 3.19) [358],... [Pg.124]

Guerra, G. Cavallo, L. Moscardi, G. Vacatello, M. Corradini, P. Back-skip of the growing chain at model complexes for the metallocene polymerization catalysis. Macromolecules 1996, 29, 4834. [Pg.1612]

The propagation was considered to proceed with unbroken alternation between (S) and (R) complexes. Thus, (S) and (R) complexes were regarded as kineti-cally separated which implies that no back-skip occurs. The treatment was also limited to encompassing stereospecificity only, i.e., regiospecihcity was not included. [Pg.297]

Careful comparison of calculated and observed pentad distributions at a range of different temperatures thus indicates that back-skip is important for explaining the stereospecificity of 4—6 above 30—50 °C, but is unnecessary for explaining the observed isospecificity of 7. [Pg.300]

See other pages where Back-skip is mentioned: [Pg.22]    [Pg.25]    [Pg.25]    [Pg.26]    [Pg.219]    [Pg.648]    [Pg.109]    [Pg.117]    [Pg.119]    [Pg.121]    [Pg.145]    [Pg.145]    [Pg.155]    [Pg.155]    [Pg.163]    [Pg.100]    [Pg.326]    [Pg.289]    [Pg.291]    [Pg.292]    [Pg.294]    [Pg.299]    [Pg.300]    [Pg.300]    [Pg.362]    [Pg.395]    [Pg.402]    [Pg.403]   
See also in sourсe #XX -- [ Pg.648 ]

See also in sourсe #XX -- [ Pg.648 ]



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Back-skip mechanism, growing chains

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