Dependence of Electrical Conductivity on Phase Morphology for Graphene Selectively Located at the Interface of Polypropylene/Polyethylene Composites

Tu, Ce; Nagata, Kenji; Yan, Shouke

doi:10.3390/nano12030509

Cited by 11 publications

(5 citation statements)

References 33 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…This, in turn, impacts the spectral distribution of the heat transfer and can result in significant enhancements or suppressions compared to in-phase or non-interacting graphene configurations. The energy-dependent conductivity of graphene can be related to its relaxation time τ and Fermi energy EF using the equation (S. Biehs, 2011) (Ce Tu, 2022:…”

Section: Out-of-phase Graphene Layers and Dielectric Interactionmentioning

confidence: 99%

Near-Field Radiative Heat Transfer Between Out-of-Phase Graphene-Covered Silica

Petita,

Favreau,

Soucy

2023

Preprint

View full text Add to dashboard Cite

Near-field radiative heat transfer has garnered significant attention due to its potential applications in various fields, including thermal management, energy conversion, and nanoscale heat transport. Graphene, a two-dimensional material with exceptional thermal properties, has emerged as a promising candidate for enhancing radiative heat transfer at nanoscale distances. In this study, we investigate the near-field radiative heat transfer between out-of-phase graphene-covered silica surfaces, aiming to understand the underlying mechanisms, quantify the heat transfer enhancement, and explore potential applications. Silica is widely used in transistors and enhanced heat transfer, can lead to huge benefits in board design.

show abstract

Section: Out-of-phase Graphene Layers and Dielectric Interactionmentioning

confidence: 99%

Near-Field Radiative Heat Transfer Between Out-of-Phase Graphene-Covered Silica

Petita,

Favreau,

Soucy

2023

Preprint

View full text Add to dashboard Cite

show abstract

“…The effectiveness of RGO in reducing the interfacial tension between the two polymers and promoting compatibilization suggests its potential as a viable substitute for traditional compatibilizers when blending otherwise incompatible polymers. In another study, thermally reduced graphene oxide (TRG) was selectively localized at the interface of the PP and PE blend by tailoring processing sequences [15]. The lower interfacial tension of TRG with PE prompts its localization in PE within the PP/PE blend; however, when subjected to pre-blending with PP followed by the addition of PE, it can be localized at the interface.…”

Section: Introductionmentioning

confidence: 99%

Entropy Barrier Mitigation and Harnessing Localized Upcycled Graphene Nanoplatelets in Polypropylene/High-Density Polyethylene Nanoblends

Şahin Dündar,

Saner Okan

2024

J Inorg Organomet Polym

View full text Add to dashboard Cite

In pursuit of a sustainable future, the focus on thermoplastic compounding emerges as a transformative avenue. Strategically blending and compounding thermoplastics unlock the potential for eco-friendly materials, addressing pressing environmental concerns. Polymer blending is a widely utilized technique that offers significant advantages in terms of cost-effectiveness and the development of materials with diverse properties. However, achieving compatibility between polymers remains a challenge due to their non-negligible entropy, particularly in the case of immiscible polymers like Polypropylene (PP) and High-Density Polyethylene (HDPE). The success of such systems heavily depends on optimizing factors such as additive selection, mixing methodology, composition, and processing conditions. Despite the extensive industrial usage of polymers like PP and HDPE, there is still limited understanding regarding the impact of blending these polymers, especially when graphene is introduced. This study addresses these challenges by overcoming the entropy barrier between PP and HDPE using a high shear rate thermo-kinetic mixer and employing upcycled graphene nanoplatelets (GNP) as a type of low-cost graphene material through interface engineering. The GNP content in the blends ranged from 0 to 1 wt%, and through meticulous selection of the polymer weight fraction and the use of minimal GNP content, GNP was strategically localized at the blend interface. This resulted in remarkable mechanical performance achieved through the optimized manufacturing technique. Incorporating 0.1 wt% GNP resulted in a significant 38% increase in tensile modulus, while flexural modulus and flexural strength saw respective increments of 39% and 22% compared to neat PP. Further enhancements were observed with higher GNP contents. This study illuminates the transformative potential of thermoplastic compounding as a key driver toward a sustainable future. Graphical Abstract

show abstract

“…A second approach is to use an immiscible polymer blend instead of a single polymer as the matrix to achieve the segregated network, through the concept of 'double percolation' [6,7]. Depending on thermodynamic properties, the filler might (1) distribute evenly in the two phases, in which case there is no advantage over a single polymer; (2) have preference to be one polymer phase than the other; or (3) it may segregate and concentrate in the regions between the two-phase boundaries leading to connectivity at low concentrations.…”

Section: Introductionmentioning

confidence: 99%

Mouldable Conductive Plastic with Optimised Mechanical Properties

Anis,

Alhamidi,

Bashir

et al. 2024

Polymers

View full text Add to dashboard Cite

This paper investigates making an injection mouldable conductive plastic formulation that aims for conductivity into the electromagnetic interference (EMI) shielding range, with good mechanical properties (i.e., stiffness, strength, and impact resistance). While conductivity in the range (electrostatic charge dissipation) and EMI shielding have been attained by incorporating conductive fillers such as carbon black, metals powders, and new materials, such as carbon nanotubes (CNTs), this often occurs with a drop in tensile strength, elongation-to-break resistance, and impact resistance. It is most often the case that the incorporation of high modulus fillers leads to an increase in modulus but a drop in strength and impact resistance. In this work, we have used short carbon fibres as the conductive filler and selected a 50/50 PBT/rPET (recycled PET) for the plastic matrix. Carbon fibres are cheaper than CNTs and graphenes. The PBT/rPET has low melt viscosity and crystallises sufficiently fast during injection moulding. To improve impact resistance, a styrene-ethylene-butadiene-styrene (SEBS) rubber toughening agent was added to the plastic. The PBT/rPET had very low-impact resistance and the SEBS provided rubber toughening to it; however, the rubber caused a drop in the tensile modulus and strength. The short carbon fibre restored the modulus and strength, which reached higher value than the PBT/rPET while providing the conductivity. Scanning electron microscope pictures showed quite good bonding of the current filler (CF) to the PBT/rPET. An injection mouldable conductive plastic with high conductivity and raised modulus, strength, and impact resistance could be made.

show abstract

Dependence of Electrical Conductivity on Phase Morphology for Graphene Selectively Located at the Interface of Polypropylene/Polyethylene Composites

Cited by 11 publications

References 33 publications

Near-Field Radiative Heat Transfer Between Out-of-Phase Graphene-Covered Silica

Near-Field Radiative Heat Transfer Between Out-of-Phase Graphene-Covered Silica

Entropy Barrier Mitigation and Harnessing Localized Upcycled Graphene Nanoplatelets in Polypropylene/High-Density Polyethylene Nanoblends

Mouldable Conductive Plastic with Optimised Mechanical Properties

Contact Info

Product

Resources

About