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Abstract
Due to their good mechanical properties, low density, and ease of processing polymer nanocomposites are of interest for a multitude of applications in the automotive, electronics, and leisure industry. Besides having an impact on short-term mechanical performance of polymers, the addition of nanoreinforcements can have also a significant effect on long-term properties such as the resistance to static (creep) and cyclic (fatigue) loadings. However, despite its significance there is a shortage of long-term mechanical performance data for thermoplastic-based polymer nanocomposites. Reason being that existing characterization methods for long-term performance and durability are time consuming and limited in their applicability. Here, an engineering approach to predict long-term time-to-failure of polycarbonate/carbon nanotube (PC/CNT) nanocomposites is presented based on short-term experimentation with an application to both creep and fatigue. Results showed that the addition of CNTs had an opposite effect on two important long-term failure mechanisms. Addition of CNTs lead to improvements in durability in the plasticity-controlled failure regime, whereas it had an adverse effect in the slow crack growth-controlled regime, meaning that in the latter regime nanocomposite performance was significantly less than that of the neat polymer matrix.
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Details
1 Eindhoven University of Technology, Department of Mechanical Engineering, Materials Technology Institute, Eindhoven, MB, Netherlands;; Dutch Polymer Institute (DPI), Eindhoven, AB, Netherlands;
2 SABIC, Bergen op Zoom, PX, Netherlands;
3 School of Engineering and Materials Science, and Materials Research Institute, Queen Mary University of London, London, United Kingdom
4 Eindhoven University of Technology, Department of Mechanical Engineering, Materials Technology Institute, Eindhoven, MB, Netherlands;





