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Polymerization metallocene

Olefin Polymerization. Titanates having a carbon—titanium bond are extensively kivolved ki Ziegler-Natta and metallocene polymerization of... [Pg.161]

APAOs has limited their utility in a number of applications. The broad MWD produces poor machining and spraying, and the low cohesive strength causes bond failures at temperatures well below the softening point when minimal stress is applied. To address these deficiencies, metallocene-polymerized materials have been developed [17,18]. These materials have much narrower MWDs than Ziegler-Natta polymerized materials and a more uniform comonomer distribution (see Table 3). Materials available commercially to date are better suited to compete with conventional EVA and EnBA polymers, against which their potential benefits have yet to be realized in practice. [Pg.717]

Marks TJ, Yang S, Stem CL, Chen YXE (1996) Organo-Lewis acids as cocatalysts in cationic metallocene polymerization catalysis. Unusual characteristics of sterically encumbered Tris(perfluorobiphenyl)borane. J Am Chem Soc 118 12451-12452... [Pg.64]

Marks TJ, Stern CL, Chen YXC (1997) Very large counteranion modulation of cationic metallocene polymerization activity and stereoregulation by a sterically congested (pefluoroaryl) fluoroaluminate. J Am Chem Soc 119 2582-2583... [Pg.64]

Molecular weight distributions in metallocene polymerizations are generally in the range of 2-5. PDI is often broadened at higher polymerization temperatures, which may indicate that more than one type of propagating species is present. In general, the more... [Pg.680]

Long-chain branching (LCB), generally less than 0.1 branch per 1000 carbons, has been observed in some metallocene polymerizations of ethylene and propene [Nele and Soares, 2002 Soares, 2002 Weng et al., 2002]. The presence of even small amounts of LCB improves melt strength and melt processability of narrow PDI polymers. Thus, it is often useful to choose conditions, such as the metallocene, temperature, and other reaction conditions, that deliberately introduce long chain branching. [Pg.682]

Block copolymers have been successfully synthesized because many metallocene polymerizations of MMA proceed as living polymerizations, and it is possible to have a single one-way crossover from carbanion (alkene) polymerization to MMA (enolate) polymerization with metallocene and related initiators, especially when group 3 transition metal initiators are used [Boffa and Novak, 2000 Desurmont et al., 2000a,b Jin and Chen, 2002 Yasuda et al., 1992],... [Pg.702]

Examples of catalytic reactions and processes relevant to hydrocarbon chemistry are numerous. The technologies of the oil refinery with extremely low (<0.1) E factors are excellent examples demonstrating the possibilities that can be achieved by the development of selective catalytic methods, particularly by the use of various solid acids (see detailed discussions in Chapter 2). Further examples of commercially highly successful processes are the oxidation catalyst TS-1 developed by Enichem researchers160 161 (see Sections 9.1.1, 9.2.1, and 9.4.1), the homogeneous aqueous-phase Rh-catalyzed hydroformylation (see Sections 7.1.3 and 7.4.1), and single-site metallocene polymerization catalysts, which allow the preparation of tailored polymers with new properties (see Sections 13.3.2).162-164... [Pg.815]

Table 10. Changing the polymerization behavior from syndiotaetic via hemiisotactie to isotactic by introducing substituents in Cs symmetric metallocene. Polymerizations were carried out at 60 °C in 11 of liquid propene... Table 10. Changing the polymerization behavior from syndiotaetic via hemiisotactie to isotactic by introducing substituents in Cs symmetric metallocene. Polymerizations were carried out at 60 °C in 11 of liquid propene...
Many examples of such eliminations have now been seen for the f-block and for d metals. This type of /3-aIkyl elimination is recognized as an important chain transfer step in Ziegler-Natta and metallocene polymerization catalysis. When it occurs the polymer chain terminates in a C=C bond (equation 2) and in certain cases the aUcene chain end can undergo reinsertion and get back into the polymer growth... [Pg.5748]

The active species in MAO cocatalyzed metallocene polymerization is likely a coordinatively unsaturated cationic complex, as in 9-24 (for a zirconium-based metallocene), where substituents on the metal atoms have been omitted for clarity. The Zr—O—A1 bond withdraws electron density from the Zr atom. The mechanism for ethylene polymerization is proposed to be as follows, where the monomer forms a t-complex with the transition metal [ 14] ... [Pg.343]

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See also in sourсe #XX -- [ Pg.51 ]

See also in sourсe #XX -- [ Pg.107 , Pg.758 , Pg.759 ]



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Alkene polymerization Ziegler-Natta catalysis and metallocene catalysts

Alkene polymerization, metallocene

Alkene polymerization, metallocene catalyzed

Block copolymer metallocene polymerization

Branching in Metallocene Polymerizations

Branching metallocene polymerization

Coordination polymerization metallocene

Copolymers olefin-functionalized metallocene polymerization

Dienes, metallocene-catalyzed polymerization

Ethylene polymerization, metallocene based

Kinetics metallocene polymerization

Metallocene Ziegler-Natta polymerization

Metallocene catalysts for olefin polymerization

Metallocene catalysts olefin polymerization

Metallocene catalysts polymerization mechanism

Metallocene polymers ring-opening polymerization

Metallocene-Catalyzed Polymerization of Propylene to Highly Isotactic Polypropylene in Organic Suspension

Metallocene-based Olefin Polymerization

Metallocene-catalyzed propylene polymerization

Metallocene-initiated polymerization

Metallocene-initiated polymerization branching

Metallocene-initiated polymerization coinitiator

Metallocene-initiated polymerization kinetics

Metallocene-initiated polymerization supported

Metallocenes olefin-functionalized metallocene polymerization

Metallocenes polymerization catalysts

Metallocenes propene polymerization

Metallocenes site-controlled stereospecific polymerizations

Metallocenes, polymerization

Neutral Group 3 Metallocene Complexes as Catalysts of Polymerization

Newer Metallocene Catalysts for Olefin Polymerization

Olefin-functionalized metallocene polymerization

Polymeric metallocenes

Polymeric metallocenes

Polymerization 1,5-hexadiene with metallocene catalysts

Polymerization metallocene catalysts

Polymerization metallocene catalyzed

Polymerization metallocene-catalysis

Polymerization of Olefin-Functionalized Metallocenes

Polymerization with Metallocene Catalysts

Polymerization, by metallocene catalysts

Polypropylene metallocene polymerization catalysts

Ring-opening polymerization metallocenes

Stereoselective polymerization metallocene initiator

Stereospecific polymerizations homogeneous metallocenes

Stereospecificity metallocene-catalyzed polymerization

Ziegler-Natta polymerization Metallocene catalysts

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