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David, Eric
in Cooperation with on an Cooperation-Score of 37%
Topics
Publications (8/8 displayed)
- 2024Effect of environmental temperature and semi‐crystalline order on the toughening of polyamide 1010 by <scp>2D</scp> nanomaterials
- 2024Balancing thermal conductivity, dielectric, and tribological properties in polyamide 1010 with 2D nanomaterialscitations
- 2019Deployment of 4P, the high-speed phenotyping data processing platform on the France Grilles infrastructure.
- 2019Deployment of 4P, the high-speed phenotyping data processing platform on the France Grilles infrastructure.
- 2019Dielectric properties of epoxy/POSS and PE/POSS systems
- 2018Electrical Breakdown Properties of Clay-Based LDPE Blends and Nanocompositescitations
- 2016Dielectric properties of epoxy/montmorillonite nanocomposites and nanostructured epoxy/SiO2/Montmorillonite Microcompositescitations
- 2016Functional Nanomaterials For Electric Power Industry
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article
Balancing thermal conductivity, dielectric, and tribological properties in polyamide 1010 with 2D nanomaterials
Abstract
<jats:title>Abstract</jats:title><jats:p>Low electrical conductivity and high heat dissipation are crucial for electronic packaging materials. Additionally, friction is critical for the lifespan and energy efficiency of components. To address these requirements, polymer nanocomposites based on bio‐based polyamide 1010 and ultra‐low contents of 2D nanomaterials were produced by melt‐blending. Graphene oxide, hexagonal boron nitride, and molybdenum disulfide were selected for their two‐dimensional structure and electrical insulation, providing high thermal conductivity while preserving the polymer's dielectric nature. Hybrid nanocomposites were also produced to explore potential synergistic effects. Results showed all compositions maintained the polymer's intrinsic dielectric properties. Although the friction coefficient increased slightly compared with neat polyamide, all nanocomposites remained within the low‐friction range required for low‐friction materials. Thermal conductivity improved by 5%–10% compared with unfilled polyamide, with hybrid systems performing slightly better, indicating a minor synergistic effect. Despite these enhancements being modest compared with the literature, achieving high thermal conductivity usually requires over 20 wt% of nanofiller, which is detrimental to mechanical performance. In this study, at most 0.5 wt% was used, with composites being obtained directly through melt‐blending. This highlights their potential as low‐content additives for thermal interface materials without compromising other essential properties.</jats:p>