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1. High-density polyethylene—an inert additive with stabilizing effects on organic field-effect transistors

   https://doi.org/10.1039/D0TC03173A  

   Scaccabarozzi, Alberto D.; Basham, James I.; Yu, Liyang; Westacott, Paul; Zhang, Weimin; Amassian, Aram; McCulloch, Iain; Caironi, Mario; Gundlach, David J.; Stingelin, Natalie (November 2020, Journal of Materials Chemistry C)

   null (Ed.)

   Organic electronics technologies have attracted considerable interest over the last few decades and have become promising alternatives to conventional, inorganic platforms for specific applications. To fully exploit the touted potential of plastic electronics, however, other prerequisites than only electronic functions need to be fulfiled, including good mechanical stability, ease of processing and high device reliability. A possible method to overcome these issues is the employment of insulating:semiconducting polymer blends, which have been demonstrated to display favourable rheological and mechanical properties, generally provided by the insulating component, without negatively affecting the optoelectronic performance of the semiconductor. Here, we demonstrate that binary blends comprising the semicrystalline high-density polyethylene (HDPE) in combination with hole- and electron-transporting organic semiconductors allow fabrication of p-type and n-type thin-film transistors of notably improved device stability and, in some scenarios, improved device performance. We observe, for example, considerably lower subthreshold slopes and drastically reduced bias-stress effects in devices fabricated with a hole-transporting diketopyrrolopyrrole polymer derivative when blended with HDPE and significantly enhanced charge-carrier mobilities and shelf life in case of transistors made with blends between HDPE and the electron-transporting poly{[ N , N ′-bis(2-octyldodecyl)-naphthalene-1,4,5,8-bis(dicarboximide)2,6-diyl]- alt -5,5′-(2,2′-bithiophene)}, i.e. P(NDI2OD-T2), also known as N2200, compared to the neat material, highlighting the broad, versatile benefits blending semiconducting species with a semicrystalline commodity polymer can have. 

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2. Continuous one-pot melt extrusion approach for high-density polyethylene-based vitrimers

   Rabnawaz, Muhammad (August 2023, ACS)

   In this presenation, I will discuss a continuous melt extrusion approach in one go for the synthesis of high-density polyethylene (HDPE)-based vitrimers. Vitrimers are produced with two grafting two agents, with maleic anhydride serving as a reactive agent to facilitate crosslinking while dimethyl maleate helped to lower the surface energy for better maleation. This improved property is reflected in the 2 wt% system, where the crosslinking density had doubled and enhanced the stiffness of the material. Overall, these vitrimers had enhanced tensile stress at break and impact resistance as compared to that of HDPE, while yet having a similar melting temperature and tensile stress at yield. The crystallinity of the polymers decreased and thus these materials may be strong candidates for 3D printing applications as they are less susceptible to the warping issues that are encountered with unmodifed HDPE. These vitrimers are reprocessable with torque pf ~ 30 Nm, and thus they can be readily recycled despite the crosslinking of layers which imparts them with better mechanical and thermal properties. 

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3. Unlocking enhanced thermal conductivity in polymer blends through active learning

   https://doi.org/10.1038/s41524-024-01261-2  

   Xu, Jiaxin; Luo, Tengfei (April 2024, npj Computational Materials)

   Abstract Polymers play an integral role in various applications, from everyday use to advanced technologies. In the era of machine learning (ML), polymer informatics has become a vital field for efficiently designing and developing polymeric materials. However, the focus of polymer informatics has predominantly centered on single-component polymers, leaving the vast chemical space of polymer blends relatively unexplored. This study employs a high-throughput molecular dynamics (MD) simulation combined with active learning (AL) to uncover polymer blends with enhanced thermal conductivity (TC) compared to the constituent single-component polymers. Initially, the TC of about 600 amorphous single-component polymers and 200 amorphous polymer blends with varying blending ratios are determined through MD simulations. The optimal representation method for polymer blends is identified, which involves a weighted sum approach that extends existing polymer representation from single-component polymers to polymer blends. An AL framework, combining MD simulation and ML, is employed to explore the TC of approximately 550,000 unlabeled polymer blends. The AL framework proves highly effective in accelerating the discovery of high-performance polymer blends for thermal transport. Additionally, we delve into the relationship between TC, radius of gyration (R_g), and hydrogen bonding, highlighting the roles of inter- and intra-chain interactions in thermal transport in amorphous polymer blends. A significant positive association between TC andR_gimprovement and an indirect contribution from H-bond interaction to TC enhancement are revealed through a log-linear model and an odds ratio calculation, emphasizing the impact of increasingR_gand H-bond interactions on enhancing polymer blend TC. 

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4. Compositional analysis of multilayered plastic constituents and constituent mixtures using benchtop ¹ H NMR spectroscopy

   https://doi.org/10.1002/mrc.5450  

   Senthil_Kumar, Harrish_Kumar; Noh, Yoorae; Bachmann, Adam_L; Beckingham, Bryan_S (May 2024, Magnetic Resonance in Chemistry)

   Abstract Multilayered plastics are widely used in food packaging and other commercial applications due to their tailored functional properties. By layering different polymers, the multilayered composite material can have enhanced mechanical, thermal, and barrier properties compared to a single plastic. However, there is a significant need to recycle these multilayer plastics, but their complex structure offers significant challenges to their successful recycling. Ultimately, the use and recycling of these complex materials requires the ability to characterize the composition and purity as a means of quality control for both production and recycling processes. New advances and availability of low‐field benchtop¹H NMR spectrometers have led to increasing interest in its use for characterization of multicomponent polymers and polymer mixtures. Here, we demonstrate the capability of low‐field benchtop¹H NMR spectroscopy for characterization of three common polymers associated with multilayered packaging systems (low‐density polyethylene [LDPE], ethylene vinyl alcohol [EVOH], and Nylon) as well as their blends. Calibration curves are obtained for determining the unknown composition of EVOH and Nylon in multilayered packaging plastics using both the EVOH hydroxyl peak area and an observed peak shift, both yielding results in good agreement with the prepared sample compositions. Additionally, comparison of results extracted for the same samples characterized by our benchtop spectrometer and a 500‐MHz spectrometer found results to be consistent and within 2 wt% on average. Overall, low‐field benchtop¹H NMR spectroscopy is a reliable and accessible tool for characterization of these polymer systems. 

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5. Polyethylene Incorporating Diels–Alder Comonomers: A “Trojan Horse” Strategy for Chemically Recyclable Polyolefins

   https://doi.org/10.1002/anie.202301927  

   Parke, Sarah M; Lopez, Jaqueline C; Cui, Shilin; LaPointe, Anne M; Coates, Geoffrey W (July 2023, Angewandte Chemie International Edition)

   Abstract Polyolefins with periodic unsaturation in the backbone chain are sought after for synthesizing chemically recyclable polymers or telechelic polyolefin macromonomers. Here we introduce a bottom‐up synthesis of unsaturated high‐density polyethylene (HDPE) via copolymerization of ethylene with dimethyl 7‐oxabicyclo[2.2.1]hepta‐2,5‐diene‐3,5‐dicarboxylate followed by post‐polymerization retro‐Diels–Alder to unveil hidden double bonds in the polymer backbone. The incorporation of this “Trojan Horse” comonomer was varied and a series of unsaturated HDPE polymers with block lengths of 1.2, 1.9, and 3.5 kDa between double bonds was synthesized. Cross metathesis of unsaturated HDPE samples with 2‐hydroxyethyl acrylate yielded telechelic ester terminated PE macromonomers suitable for the preparation of ester‐linked PE. These materials were depolymerized and repolymerized, making them suitable candidates for chemical recycling. The ester‐linked PE displayed thermal and mechanical properties comparable to commercial HDPE. 

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