Toughening mechanisms responsible for excellent crack resistance in thermoplastic nanofiber reinforced epoxies through in-situ optical and scanning electron microscopy

Epoxy is a material of choice for demanding applications thanks to its high chemical stability, stiffness, and strength. Yet, its brittle fracture behavior is an important downside for many sectors. Here, we show that the addition of electrospun thermoplastic nanofibers is a viable toughening strate...

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Veröffentlicht in:	Composites science and technology 2021-01, Vol.201, p.108504, Article 108504
Hauptverfasser:	Daelemans, Lode, Verschatse, Olivier, Heirman, Lisa, Van Paepegem, Wim, De Clerck, Karen
Format:	Artikel
Sprache:	eng
Schlagworte:	Coating Correlation analysis Crack propagation Crack tips Cracks Damage mechanics Digital image correlation Digital imaging Energy absorption Epoxy resins Fiber composites Fiber reinforced composites Fracture toughness Interfacial strength Laminates Mechanical tests Nano composites Nanofibers Nanomaterials Polyamide resins Polycaprolactone Scanning electron microscopy Stiffness Thermoplastics
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container_title	Composites science and technology
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creator	Daelemans, Lode Verschatse, Olivier Heirman, Lisa Van Paepegem, Wim De Clerck, Karen
description	Epoxy is a material of choice for demanding applications thanks to its high chemical stability, stiffness, and strength. Yet, its brittle fracture behavior is an important downside for many sectors. Here, we show that the addition of electrospun thermoplastic nanofibers is a viable toughening strategy to design nanofiber reinforced epoxy materials with excellent toughness. Moreover, the use of transparent film-like specimens allowed in-situ imaging during mechanical testing. Optical and scanning electron microscopy, digital image correlation and crack length measurements are used to analyze the toughening mechanisms responsible for high toughening efficiency in detail. The addition of polyamide and polycaprolactone nanofibers resulted in an increased plastic energy uptake up to 100%. In-situ observation of the crack tip showed that the main energy-absorbing mechanism was due to bridging nanofibers. There was a profound decrease in toughening efficiency when nanofibers lacked sufficient adhesion with the matrix only when they were oriented parallel with the crack growth direction. The profound understanding of such underlying mechanisms opens up material design in applications where high toughness is required like adhesives, coatings, and fiber-reinforced composite laminates. [Display omitted] •Thermoplastic nanofibers provide excellent toughness to brittle epoxy.•Specimen design allows in-situ optical and scanning electron microscopy for analyzing the toughening mechanisms in detail.•Bridging nanofibers behind the crack tip are the main cause of toughness.•Epoxy failure mode becomes more stable when toughened with nanofibers.•The developed method can be utilized to determine nanofiber/matrix adhesion as well.
doi_str_mv	10.1016/j.compscitech.2020.108504
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subjects	Coating Correlation analysis Crack propagation Crack tips Cracks Damage mechanics Digital image correlation Digital imaging Energy absorption Epoxy resins Fiber composites Fiber reinforced composites Fracture toughness Interfacial strength Laminates Mechanical tests Nano composites Nanofibers Nanomaterials Polyamide resins Polycaprolactone Scanning electron microscopy Stiffness Thermoplastics
title	Toughening mechanisms responsible for excellent crack resistance in thermoplastic nanofiber reinforced epoxies through in-situ optical and scanning electron microscopy
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