Redox Potential as a Predictor of Polyethylene Branching Using Nickel α-Diimine Catalysts

Doerr, Alicia M.; Curry, Matthew R.; Chapleski, Robert C.; Burroughs, Justin M.; Lander, Elizabeth K.; Roy, Sharani; Long, Brian K.

doi:10.1021/acscatal.1c03646

Cited by 20 publications

(12 citation statements)

References 56 publications

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“…Many factors such as molecular weight, molecular weight distribution, and branching content strongly in uence the miscibility of polyole n blends, which is crucial to realizing desired properties for multimodal polyole ns. [30][31][32][33][34][35] As expected, good miscibility is di cult to achieve for mixtures of linear and branched polyole ns. 36,37 This poor miscibility is exponentially ampli ed for the above-mentioned bimodal polar functionalized polyole ns, since the low-molecular-weight fraction is both more branched and more polar than the high-molecular-weight fraction.…”

Section: Introductionmentioning

confidence: 58%

A Co-Anchoring Strategy for the Synthesis of Polar Bimodal Polyethylene

Chen

Zou

Wang

et al. 2022

Preprint

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Since polar groups can poison the metal centers in catalysts, the incorporation of polar comonomers usually comes at the expense of catalytic activity and polymer molecular weight. In this contribution, we demonstrate polar bimodal polyethylene as a potential solution to this trade-off. The more-polar/more-branched low-molecular-weight fraction provided polarity and processability, while the less-polar/less-branched high-molecular-weight fraction provided mechanical and melt properties. To achieve high miscibility between these two fractions, three synthetic routes were investigated: mixtures of homogeneous catalysts, separately supported heterogeneous catalysts, and a co-anchoring strategy (CAS) to heterogenize different homogeneous catalysts on one solid support. The CAS route was the only viable strategy for the synthesis of polar bimodal polyethylene with good molecular level entanglement and minimal phase separation. This produced polyolefin materials with excellent mechanical properties, surface/dyeing properties, gas barrier properties, as well as extrudability and 3D-printability.

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Section: Introductionmentioning

confidence: 58%

A Co-Anchoring Strategy for the Synthesis of Polar Bimodal Polyethylene

Chen

Zou

Wang

et al. 2022

Preprint

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“…Apart from the steric hindrance effect, is there any other property of ligand that can tune the final structure of the AuCd cluster? As is well known, the electronic properties of substituents play very important roles in organic reactions. , Does it also work in the preparation of metal clusters, particularly, cluster transformation or doping? To eliminate the influence of the steric hindrance effect, three para-substituted thiophenols, e.g., 4- tert -butyl-benzenethiol (TBBT), 4-methoxybenzenethiol (4MOBT), and 4-(trifluoromethyl)thiophenol (4TMBT), are selected in this study to investigate their function in Cd doping.…”

Section: Resultsmentioning

confidence: 99%

Identifying the Real Chemistry of the Synthesis and Reversible Transformation of AuCd Bimetallic Clusters

et al. 2022

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The capability of precisely constructing bimetallic clusters with atomic accuracy provides exciting opportunities for establishing their structure–property correlations. However, the chemistry (the charge state of precursors, the property of ligands, the amount of dopant, and so forth) dictating the fabrication of clusters with atomic-level control has been a long-standing challenge. Herein, based on the well-defined Au25(SR)18 cluster (SR = thiolates), we have systematically investigated the factors of steric hindrance and electronic effect of ligands, the charge state of Au25(SR)18, and the amount of dopant that may determine the structure of AuCd clusters. It is revealed that [Au19Cd3(SR)18]− can be obtained when a ligand of smaller steric hindrance is used, while Au24Cd(SR)18 is attained when a larger steric hindrance ligand is used. In addition, negatively charged [Au25(SR)18]− is apt to form [Au19Cd3(SR)18]− during Cd doping, while Au24Cd(SR)18 is produced when neutral Au25(SR)18 is used as a precursor. Intriguingly, the reversible transformation between [Au19Cd3(SR)18]− and Au24Cd(SR)18 is feasible by subtly manipulating ligands with different steric hindrances. Most importantly, by introducing the excess amount of dopant, a novel bimetallic cluster, Au4Cd4(SR)12 is successfully fabricated and its total structure is fully determined. The electronic structures and the chirality of Au4Cd4(SR)12 have been elucidated by density functional theory (DFT) calculations. Au4Cd4(SR)12 reported herein represents the smallest AuCd bimetallic cluster with chirality.

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“…Polyethylene (PE) is a commonly used plastic material with a wide range of applications. − The research studies of PE have also received extensive attention for its synthesis, modification, − application, − degradation, , etc. Foaming technology has been widely applied in PE products, such as injection foaming and rotational foaming. − The foaming behavior directly affects the performance of the PE foaming products.…”

Section: Introductionmentioning

confidence: 99%

Significantly Tunable Foaming Behavior of Blowing Agent for the Polyethylene Foam Resin with a Unique Designed Blowing Agent System

Chen,

Huang

2024

ACS Omega

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The chemical blowing agent plays a crucial role in enhancing the performance of the polyethylene (PE) foaming resin during the rotational foaming process. Previously, the conventional blowing agent of the PE resin commonly used pure azodicarbonamide (AZ). It had the unavoidable drawbacks of releasing NH 3 and exhibiting strong reactions during the rotational foaming process. Meantime, pure AZ had a relatively high decomposition temperature, resulting in a sharp foaming process. To address the above issues, this work developed a uniquely designed blowing agent system. In this study, a novel blowing agent for the PE resin was successfully synthesized by a one-pot method. This blowing agent consisted of an activator and AZ, which exhibited a lower decomposition temperature and a milder decomposition rate than AZ. The activator was constituted of small-sized ammonium dihydrogen phosphate on the AZ surface, which could be decomposed properly and deliver phosphoric acid and H 2 O during the foaming process. Then, AZ reacted with H 2 O under phosphoric acid catalysis. Also, this reaction generated CO 2 emission while reducing the emission of NH 3 through recombination with phosphoric acid. Moreover, phosphoric acid catalysis caused a decrease in the AZ decomposition temperature. Meantime, the thermal coupling appeared during the foaming process, which could further reduce the decomposition rate. Consequently, the small activator played a key role in regulating cell formation and diffusion. Compared to AZ, the novel blowing agent system significantly reduced the cell diameter of the PE foam resin and enhanced its flexural modulus by 50%. Furthermore, the novel blowing agent facilitated better demolding performance and improved the surface morphology of the PE foam product. This research provides significant foaming behavior regulation for the PE resin during industrial applications.

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Redox Potential as a Predictor of Polyethylene Branching Using Nickel α-Diimine Catalysts

Cited by 20 publications

References 56 publications

A Co-Anchoring Strategy for the Synthesis of Polar Bimodal Polyethylene

A Co-Anchoring Strategy for the Synthesis of Polar Bimodal Polyethylene

Identifying the Real Chemistry of the Synthesis and Reversible Transformation of AuCd Bimetallic Clusters

Significantly Tunable Foaming Behavior of Blowing Agent for the Polyethylene Foam Resin with a Unique Designed Blowing Agent System

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