Ideal Polyethylene Nanocrystals

Osichow, Anna; Rabe, Christian; Vogtt, Karsten; Narayanan, Theyencheri; Harnau, Ludger; Drechsler, Markus; Ballauff, Matthias; Mecking, Stefan

doi:10.1021/ja4052334

Cited by 74 publications

(118 citation statements)

References 22 publications

(42 reference statements)

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“…To understand their role in catalysis, we investigated the influence of long perfluoroalkyl substituents (linear C 6 F 13 groups) in different established salicylaldiminato Ni II motifs under a set of polymerization reaction conditions. We targeted the N ‐(quar)terphenyl‐based 1‐R F /L and 2‐R F /L (Figure ), known to be active in aqueous and nonaqueous ethylene polymerization to linear high‐molecular‐weight polyethylene . We also modified the N‐naphthyl‐type catalyst 3‐R F /L (Figure ), capable of a controlled/living ethylene polymerization in a variety of solvents, and introduced C 6 F 13 ‐substituents to selected positions .…”

Section: Resultsmentioning

confidence: 99%

“…During polymerization in aqueous surfactant solution with Ni II salicylaldiminato catalysts, the polyethylene is formed in the very unusual form of nanoscale single crystals . They are characterized by a high degree of order, which arises from the unique particle growth mechanism, where the active center's growing chain is directly deposited on the crystal growth front, leaving no opportunity for any disorder . This process allows effective generation of anisotropic polymer nanoparticles, which are otherwise difficult to access…”

Section: Resultsmentioning

confidence: 99%

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Remote Perfluoroalkyl Substituents are Key to Living Aqueous Ethylene Polymerization

et al. 2020

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In various nickel(II) salicylaldiminato ethylene polymerization catalysts, which are a versatile mechanistic probe for substituent effects, longer perfluoroalkyl groups exert a strong effect on catalytic activities and polymer microstructures compared to the trifluoromethyl group. This effect is accounted for by a reduced electron density on the active sites, and is also supported by electrochemical studies. Thus, β‐hydride elimination, the key step of chain transfer and branching pathways, is disfavored while chain‐growth rates are enhanced. This enhancement occurs to an extent that enables living polymerizations in aqueous systems to afford ultra‐high‐molecular‐weight polyethylene for various chelating salicylaldimine motifs. These findings are mechanistically instructive as well as practically useful for illustrating the potential of perfluoroalkyl groups in catalyst design.

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Section: Resultsmentioning

confidence: 99%

Section: Resultsmentioning

confidence: 99%

Remote Perfluoroalkyl Substituents are Key to Living Aqueous Ethylene Polymerization

et al. 2020

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“…Confinement of polymer systems can be generally classified into three categories according to their confined environments, and they are one, two and three dimensions, respectively. Confined crystallization of polymers has been found in a variety of systems, such as polymer ultrathin films [1][2][3][4][5], polymer blends [6][7][8][9][10], block copolymers [11][12][13][14], polymer droplets [15][16][17], self-assembled polymer nanostructures [18][19][20][21][22], polymers segregated inside nanoporous templates [23][24][25][26][27][28][29] and polymer nanocomposites [30][31][32][33]. In the past few years, the crystallization of polymers or polymer segments confined in ultrathin films (thickness <100 nm), miscible polymer blends and block copolymers has been widely studied for various systems.…”

Section: Introductionmentioning

confidence: 99%

Crystalline and Spherulitic Morphology of Polymers Crystallized in Confined Systems

Xie

Bao

et al. 2017

Crystals

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Due to the effects of microphase separation and physical dimensions, confinement widely exists in the multi-component polymer systems (e.g., polymer blends, copolymers) and the polymers having nanoscale dimensions, such as thin films and nanofibers. Semicrystalline polymers usually show different crystallization kinetics, crystalline structure and morphology from the bulk when they are confined in the nanoscale environments; this may dramatically influence the physical performances of the resulting materials. Therefore, investigations on the crystalline and spherulitic morphology of semicrystalline polymers in confined systems are essential from both scientific and technological viewpoints; significant progresses have been achieved in this field in recent years. In this article, we will review the recent research progresses on the crystalline and spherulitic morphology of polymers crystallized in the nanoscale confined environments. According to the types of confined systems, crystalline, spherulitic morphology and morphological evolution of semicrystalline polymers in the ultrathin films, miscible polymer blends and block copolymers will be summarized and reviewed.

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“…Entsprechend umfassen mçgliche Anwendungsfelder Elektronik, [1][2][3][4][5][6] Optoelektronik, [7][8][9][10][11] Katalyse, [12][13][14] Energiespeicherung und Energieumwandlung [15][16][17][18][19][20] sowie Membranen. [71][72][73][74][75][76][77][78] Entsprechend dieser großen Diversität finden sich unter den 2D-Materialien sowohl Strukturen mit hoher struktureller Regularität(Kristallinität) als auch Stoffe mit geringerer interner Ordnung.Die Stärke der Bindungen, welche die Netzwerke zusammenhalten, variiert in dieser Auflistung ebenfalls stark. Beispiele sind Graphen und Graphenoxid, [1,10,23,25] Übergangsmetalldichalkogenide, [7,12,[26][27][28][29][30][31] Metalloxide und -hydroxide, [32] Metallcarbide und -nitride, [33] hexagonales Bornitrid, [34] zweidimensionale kovalente organische Gerüstverbindungen (2D-COFs) [35][36]…”

Section: Einführungunclassified

Makroskopische kristalline 2D‐Polymere

Feng

Schlüter²

2018

Angewandte Chemie

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Monolagen mit interner Periodizität können als 2D‐Polymere oder “molekulare Fischernetze” beschrieben werden. Solche Strukturen sind in der Vergangenheit durch photochemische Reaktionen in Einkristallen hergestellt worden, die aus Monomeren mit spezifisch entworfenen Strukturen bestehen. Einzelne Schichten wurden später durch Exfolierung isoliert. Diese milden Bedingungen ermöglichen zwar exzellente Kontrolle über die gebildete Struktur, allerdings ist die Ausdehnung der erhaltenen 2D‐Polymere durch die Kristallausdehnung limitiert. Dieser Aufsatz befasst sich mit Ansätzen zur Herstellung von 2D‐Polymeren mit makroskopischen lateralen Abmessungen. Solche Abmessungen sind zugänglich, wenn Polymerisationsreaktionen an Grenzflächen zwischen zwei Flüssigkeiten bzw. zwischen einer Flüssigkeit und einem Gas (besonders der Wasser/Luft‐Grenzfläche) durchgeführt werden. Damit lassen sich zwar prinzipiell 2D‐Polymere makroskopischer Größe erzeugen, allerdings eröffnen sich neue analytische Probleme. Einige dieser Herausforderungen werden besprochen und die vielversprechendsten Lösungsansätze hervorgehoben. Anhand dreier repräsentativer Strukturen demonstriert dieser Aufsatz den gegenwärtigen Stand der Technik im noch jungen Feld der 2D‐Polymeranalytik. Zuletzt werden mögliche Anwendungen für neue organische 2D‐Materialien beschrieben, z. B. als Nanomembranen, organische (opto)elektronische Komponenten oder Katalysatoren für die Wasserspaltung.

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Ideal Polyethylene Nanocrystals

Cited by 74 publications

References 22 publications

Remote Perfluoroalkyl Substituents are Key to Living Aqueous Ethylene Polymerization

Remote Perfluoroalkyl Substituents are Key to Living Aqueous Ethylene Polymerization

Crystalline and Spherulitic Morphology of Polymers Crystallized in Confined Systems

Makroskopische kristalline 2D‐Polymere

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