Highly active peroxides in the radical polymerization of ethylene under high pressure. Properties of the polymers

Luft, Gerhard; Dorn, Max

doi:10.1002/apmc.1991.051880116

Cited by 21 publications

(1 citation statement)

References 3 publications

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“…The parameter Δ H m and the melting points were derived from the second course of the DSC. The fusion enthalpy Δ H ° was estimated for a 100% crystalline polyethene to 292.9 J g −1 21…”

Section: Methodsmentioning

confidence: 99%

Different surface-substituted polyorganosiloxane microgels as support materials for MAO-type cocatalysts

Schmidt

Alt

Ebenhoch³

2001

J. Appl. Polym. Sci.

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Twenty‐five different functionalized and nonfunctionalized polyorganosiloxane microgels were applied as support materials for methylalumoxane (MAO)‐type compounds to give various heterogeneous cocatalysts which are able to activate metallocene complexes like Cp2ZrCl2 for ethene polymerization. The functionalization of the microgels has a strong influence on the properties of the catalysts and the produced polyethenes. © 2001 John Wiley & Sons, Inc. J Appl Polym Sci 80: 281–285, 2001

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Section: Methodsmentioning

confidence: 99%

Different surface-substituted polyorganosiloxane microgels as support materials for MAO-type cocatalysts

Schmidt

Alt

Ebenhoch³

2001

J. Appl. Polym. Sci.

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Activation of the high pressure polymerisation of ethylene initiated with organic peroxides by means of organoaluminium compounds

Luft

Batarseh

Dorn³

1995

Angew. Makromol. Chem.

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In the course of this study, an activator system consisting of an aluminium trialkyl compound and a Lewis base was tested for its suitability for the radical polymerisation of ethylene at high pressure. The aim of reducing the initiator consumption and the polymerisation temperature was achieved with aluminium trialkyl alone without the use of a Lewis base.Among the aluminium trialkyl compounds examined, triethyl aluminium proved to be the most effective. This effectiveness is due to the increased rate of decomposition of the peroxide as a result of which a larger amount of free radicals becomes available thus increasing the rate of polymerisation. By using an addition of 50 mole ppm triethyl aluminium to 50 mole ppm tert-butyl-perpivalate in the ethylene feed it was possible to almost double the monomer conversion at a given polymerisation temperature and to reduce by half the consumption of peroxide initiator per kg polyethylene produced. Compared with the non-activated polymerisation, the polymerisation temperature was reduced from 150 OC to 125 O C , the initiator consumption remaining the same. The costs of the triethyl aluminium activator are more than offset by the increased yield and the decrease in initiator consumption. ZUSAMMENFASSUNG:In dieser Arbeit wurde die Eignung eines aus einer Tkialkylaluminiumverbindung und einer Lewisbase bestehenden Aktivatorsystems fur die radikalische Polymerisation von Ethylen unter Hochdruck gepruft. Das Ziel, den Initiatorverbrauch zu reduzieren und die Polymerisationstemperatur abzusenken, konnte ohne die Lewisbase mit Tkialkylaluminium allein erreicht werden.Von den untersuchten Tkialkylaluminiumverbindungen erwies sich das Tkiethylaluminium als effektivstes System. Seine Wirkung beruht auf der Beschleunigung des

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Synthesis and evaluation of two new FI‐Ti catalysts for living polymerization of ethylene

Guo

Jie

Fan

et al. 2013

J of Applied Polymer Sci

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Two new FI complexes, bis[N-(3-allylsalicylidene)-pentafluoroanilinato]titanium(IV) dichloride (AFI) and bis[N-(3-propylsalicylidene)-pentafluoroanilinato]titanium(IV) dichloride (PFI) were designed and synthesized as catalysts for living polymerization of ethylene. The two complexes were characterized by elemental analysis, spectroscopy and X-ray single diffraction. The catalysts were evaluated in ethylene polymerization under atmospheric pressure. It was found that both catalysts exhibited high activity and good livingness. The effects of temperature and dMAO/Ti molar ratio on the polymerization behavior of AFI were studied in detail. Elevating temperature increased self-immobilization of the AFI catalyst, which broadened the polymer molecular weight distribution.

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Highly active peroxides in the radical polymerization of ethylene under high pressure. Properties of the polymers

Cited by 21 publications

References 3 publications

Different surface-substituted polyorganosiloxane microgels as support materials for MAO-type cocatalysts

Different surface-substituted polyorganosiloxane microgels as support materials for MAO-type cocatalysts

Activation of the high pressure polymerisation of ethylene initiated with organic peroxides by means of organoaluminium compounds

Synthesis and evaluation of two new FI‐Ti catalysts for living polymerization of ethylene

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