Influence of Metal‐Alkyls on Early‐Stage Ethylene Polymerization over a Cr/SiO<sub>2</sub> Phillips Catalyst: A Bulk Characterization and X‐ray Chemical Imaging Study

Jongkind, Maarten K.; Meirer, Florian; Bossers, Koen W.; Have, Iris C. ten; Ohldag, Hendrik; Watts, Benjamin; Kessel, Theo van; Friederichs, Nic; Weckhuysen, Bert M.

doi:10.1002/chem.202002632

Cited by 9 publications

(8 citation statements)

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“…Generally, different classes of polyethylenes result from the use of specific metal-based catalysts, of which the design and synthesis are expensive, time-consuming, and not always as rewarding as expected. Therefore, the development of tunable catalytic systems that could produce different polyethylenes is highly desirable but challenging. , One of the industrially most relevant catalyst is the chromium-based Phillips catalyst (CrO x /SiO 2 ). − Discovered in 1951 by Hogan and Banks at Phillips Petroleum, this heterogeneous catalyst allows the manufacture of one-third of the high-density polyethylene (HDPE) commercialized, which is the most widely used polymer . Although the Phillips catalyst has been studied for over 70 years by both academic and industrial scientists, the nature of the initiation process, the coordination environment and the oxidation state of the metal in the active species, and the catalytic mechanism remain a hot and sometimes controversial topic. − Furthermore, much effort has been dedicated to the development of well-defined homogeneous Cr-based catalysts, ,− that are more amenable to detailed spectroscopic and structural studies than heterogeneous catalysts.…”

Section: Introductionmentioning

confidence: 99%

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Controlling Polyethylene Molecular Weights and Distributions Using Chromium Complexes Supported by SNN-Tridentate Ligands

et al. 2022

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The diverse properties and applications of polyethylenes depend on their molecular weights, molecular weight distributions, and chain topology. Considering the importance of chromium complexes in catalytic ethylene polymerization and oligomerization, we have synthesized a series of Cr complexes (Cr1−Cr6) bearing a SNN-tridentate ligand. In the presence of MAO as cocatalyst, complexes Cr1−Cr6 exhibited moderate to extremely high activity (up to 2.4 × 10 7 g(PE) mol −1 (Cr) h −1 ) toward ethylene polymerization. The influences of the ligand and of various reaction parameters, including the nature and amount of the cocatalyst and the reaction temperature and pressure, were systematically investigated with Cr1. It was found that lower reaction temperatures (50 °C) and ethylene pressure (5 atm) and larger MAO/Cr ratios (1500) favored bimodal distributions with the dominant high-M w fraction. In contrast, higher reaction temperatures (≥80 °C) and ethylene pressure (40 atm) and lower MAO/Cr ratios (≤500) almost exclusively led to the production of low-M w polyethylene waxes with monomodal and narrow distributions. Based on DFT calculations and UV−vis−NIR spectroscopy, two types of active species generated by Cr1 and MAO were proposed to be responsible for the production of bimodal polyethylene. By tuning the structures of the Cr complexes in the Cr1−Cr6/MAO systems and the reaction conditions, polyethylenes with molecular weights ranging from low-M w waxes to UHMWPE and monomodal or bimodal distributions were readily synthesized.

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Section: Introductionmentioning

confidence: 99%

“…H NMR (400 MHz, CDCl 3 ) δ: 8.56 (s, 1 H), 8.47 (d, J = 8 5. Hz, 1 H), 8.29 (d, J = 8 5. Hz, 1 H), 8.10 (d, J = 8 4.…”

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confidence: 99%

Controlling Polyethylene Molecular Weights and Distributions Using Chromium Complexes Supported by SNN-Tridentate Ligands

et al. 2022

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“…As a result, the catalysts prepared by methods ( 1) and ( 2) produce polymers with different properties. 3,51 With method (3), only CO 2 is produced during Cr(VI) reduction, and this CO 2 is immediately released from the catalytic system. It was also experimentally verified that the Cr(VI) precursors were mostly reduced to Cr(II) sites.…”

Section: ■ Computation Detailsmentioning

confidence: 99%

“…Regarding method (2), the added Al-alkyl cocatalyst is also kept in the catalyst system and interacts with the active sites. As a result, the catalysts prepared by methods (1) and (2) produce polymers with different properties. , With method (3), only CO 2 is produced during Cr(VI) reduction, and this CO 2 is immediately released from the catalytic system. It was also experimentally verified that the Cr(VI) precursors were mostly reduced to Cr(II) sites. , Moreover, the Cr(II) produced by method (3) is able to synthesize PE with properties similar to those of the Cr(II) produced by the conventional method (1).…”

Section: Computation Detailsmentioning

confidence: 99%

Computational Insights into the Multisite Nature of the Phillips CrO_x/SiO₂ Catalyst for Ethylene Polymerization: The Perspective of Chromasiloxane Ring Size and F Modification

Huang

Liu

et al. 2022

ACS Catal.

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The famous Phillips CrO x /SiO2 catalyst is characterized by its multisite nature and the resulting broad molecular weight distribution (MWD) of its polyethylene (PE) products. However, the multiplicity of active sites and their catalytic behavior relating to the broad MWD have scarcely been studied. Given the high and comparable efficiency of calcination and F modification in regulating the active site multiplicity of this catalyst, eight polyhedral oligomeric silsesquioxane (POSS)-based cluster models comprising four-, six-, and eight-membered chromasiloxane rings (4CR, 6CR, and 8CR) were partially or fully capped by OH or F and employed for density functional theory (DFT) calculations related to C2H4 polymerization. For the OH-capped models, the results emphasized the dominant size effect of the chromasiloxane ring (CR), where the model with a smaller CR was less abundant but could produce higher-molecular-weight (MW) PE with a higher activity. The predicted MW indicated the very broad MWD of the PE products, consistent with that of the products generated from low-temperature calcinated CrO x /SiO2. However, depending on the size of the CR, these models responded unequally to F modification. Specifically, the more abundant sites with 8CR were promoted more obviously, and the MW of their PE products was increased. This makes the polymerization rate higher and the MWD of the PE narrower, which agrees with those of the PE products synthesized by F-modified CrO x /SiO2 calcined at a low temperature. Furthermore, the origin of the effects of CR size and F modification was properly illustrated in terms of both steric and electronic variations.

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“…At about 400 • C, the chromium is oxidized into the hexavalent form, which spreads out and becomes anchored onto the support as chromate or dichromate surface esters [3,[5][6][7][8][9][10][11][12][13][14]. These species are then reduced by ethylene to a lower valence, expanding the potential coordination sphere, alkylating the Cr, and forming the coordinatively unsaturated active sites [3][4][5][15][16][17][18][19][20]. Consequently, and somewhat unusually for inorganic industrial catalysts, the active sites are individually attached to the support.…”

Section: Introductionmentioning

confidence: 99%

Comparison of Support Effects on Phillips and Metallocene Catalysts

Yang

McDaniel

2021

Catalysts

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Both metallocene and Phillips chromium catalysts are used in the commercial manufacture of polyethylene. Unlike most other commercial metallocene systems, the Chevron Phillips Chemical (CPC) platform does not use methylaluminoxane or fluoroorganic boranes. Instead, the support itself serves to activate (ionize) the metallocenes, which then polymerize ethylene at high activity. Most of these solid acid supports can also be used to anchor Cr to make a Phillips catalyst. This provides an interesting opportunity to compare the polymerization responses by these two disparate systems, Phillips Cr and CPC metallocene, when supported on the same solid acid carriers. In this study, both chromium oxide and several metallocenes were deposited onto a variety of solid oxides, under a variety of conditions, and the resulting support effects were observed and compared. Although using seemingly different chemistries, the two catalyst systems exhibited a surprising number of similarities, which can be attributed to the acidity and porosity of these diverse supports.

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Influence of Metal‐Alkyls on Early‐Stage Ethylene Polymerization over a Cr/SiO₂ Phillips Catalyst: A Bulk Characterization and X‐ray Chemical Imaging Study

Cited by 9 publications

References 97 publications

Controlling Polyethylene Molecular Weights and Distributions Using Chromium Complexes Supported by SNN-Tridentate Ligands

Controlling Polyethylene Molecular Weights and Distributions Using Chromium Complexes Supported by SNN-Tridentate Ligands

Computational Insights into the Multisite Nature of the Phillips CrO_x/SiO₂ Catalyst for Ethylene Polymerization: The Perspective of Chromasiloxane Ring Size and F Modification

Comparison of Support Effects on Phillips and Metallocene Catalysts

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Influence of Metal‐Alkyls on Early‐Stage Ethylene Polymerization over a Cr/SiO2 Phillips Catalyst: A Bulk Characterization and X‐ray Chemical Imaging Study

Cited by 9 publications

References 97 publications

Controlling Polyethylene Molecular Weights and Distributions Using Chromium Complexes Supported by SNN-Tridentate Ligands

Controlling Polyethylene Molecular Weights and Distributions Using Chromium Complexes Supported by SNN-Tridentate Ligands

Computational Insights into the Multisite Nature of the Phillips CrOx/SiO2 Catalyst for Ethylene Polymerization: The Perspective of Chromasiloxane Ring Size and F Modification

Comparison of Support Effects on Phillips and Metallocene Catalysts

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Influence of Metal‐Alkyls on Early‐Stage Ethylene Polymerization over a Cr/SiO₂ Phillips Catalyst: A Bulk Characterization and X‐ray Chemical Imaging Study

Computational Insights into the Multisite Nature of the Phillips CrO_x/SiO₂ Catalyst for Ethylene Polymerization: The Perspective of Chromasiloxane Ring Size and F Modification