A unified polymer reaction engineering methodology for catalytic olefin polymerization: From reaction conditions and catalyst reaction performance to molecular and rheological properties for forward, reverse engineering and deconvolution applications

Touloupidis, Vasileios

doi:10.1002/cjce.24869

Cited by 4 publications

(2 citation statements)

References 36 publications

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“…The authors of the articles in this issue join us from many countries and institutions across the globe (Figure 1 and Table 1) to thank Archie for his enduring legacy in polymerization reaction engineering, a field of academic and industrial interest that he established practically single‐handedly. [ 1–45 ]…”

Section: Figurementioning

confidence: 99%

Archie E. Hamielec memorial issue

et al. 2023

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Section: Figurementioning

confidence: 99%

Archie E. Hamielec memorial issue

et al. 2023

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“…The potential of the proposed methodology is highlighted within a series of indicative examples, including both forward and reverse engineering, as well as deconvolution applications. [ 1 ]…”

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confidence: 99%

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2023

Can J Chem Eng

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A unified polymer reaction engineering methodology for catalytic olefin polymerization: From reaction conditions and catalyst reaction performance to molecular and rheological properties for forward, reverse engineering and deconvolution applications Vasileios TouloupidisThis work presents a unified polymer reaction engineering methodology for catalytic olefin polymerization process (singe-and multi-site catalysts). The proposed modelling approach offers a modelling pathway from polymerization recipe, to production rate and polymer microstructure, and finally to rheological properties. For the first time, the constraint of the actual reaction performance of the polymerization catalyst in the inverse rheology and microstructural deconvolution problem is introduced, limiting the solution to the most realistic molecular weight distributions (MWDs) that a specific catalyst can produce. The potential of the proposed methodology is highlighted within a series of indicative examples, including both forward and reverse engineering, as well as deconvolution applications. [1]

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Correlations of single‐point parameters of linear rheology and molecular weight distribution of polypropylene homo‐ and copolymers

Gschwendner,

Gitsas,

Gahleitner

et al. 2024

J of Applied Polymer Sci

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For various purposes, it is required to compress the shape of the molecular weight distribution (MWD) of polymers into a limited set of parameters. With increasing molecular weight and polydispersity, the MWD data obtained from chromatography become increasingly unreliable due to deficiencies in the high molecular weight region, making estimation via melt rheology more preferable. A number of empirical parameters obtained from melt rheology can be related back to MWD parameters. The target of this study is to establish the reliability of such relations for polypropylene homo‐ and copolymers. It is found that correlations between polydispersity from rheological crossover modulus and polydispersity via chromatography are not always valid. Therefore, the range of applicability must be kept in mind when attempting predictions based on these correlations because rheological measurements are sensitive to molecular characteristics in ways different from chromatography. The use of a modified polydispersity index is shown to be more reliable.

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A unified polymer reaction engineering methodology for catalytic olefin polymerization: From reaction conditions and catalyst reaction performance to molecular and rheological properties for forward, reverse engineering and deconvolution applications

Cited by 4 publications

References 36 publications

Archie E. Hamielec memorial issue

Archie E. Hamielec memorial issue

Issue Highlights

Correlations of single‐point parameters of linear rheology and molecular weight distribution of polypropylene homo‐ and copolymers

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