UV accelerated aging of unidirectional flax composites: Comparative study between recycled and virgin polypropylene matrix

UV accelerated aging of unidirectional flax composites: Comparative study between recycled and virgin polypropylene matrix

•Photooxidation affected the physico-chemical properties of UD composites with flax fibers.•Photooxidation caused surface degradation, leaving the bulk of the composite unaffected.•Recycled polypropylene composites showed good mechanical resistance to UV exposure. Previous studies on the photooxidat...

Full description

Saved in:
Bibliographic Details
Published in:Polymer degradation and stability Vol. 208; p. 110268
Main Authors: Alam, Lara, Piezel, Benoit, Sicot, Olivier, Aivazzadeh, Shahram, Moscardelli, Sandrine, Van-Schoors, Laetitia
Format: Journal Article
Language:English
Published: Elsevier Ltd 01-02-2023
Elsevier
Subjects:
Accelerated aging
Engineering Sciences
Flax fiber
Photooxidation
Physicochemical properties
Recycled polypropylene
Tensile properties
Flax fiber
Accelerated aging
Photooxidation
Physicochemical properties
Tensile properties
Recycled polypropylene
Online Access:Get full text
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:•Photooxidation affected the physico-chemical properties of UD composites with flax fibers.•Photooxidation caused surface degradation, leaving the bulk of the composite unaffected.•Recycled polypropylene composites showed good mechanical resistance to UV exposure. Previous studies on the photooxidation of natural fiber composites have focused on using short fibers and virgin matrices. In this work, unidirectional flax fiber composites with virgin and recycled polypropylene matrix were prepared by thermocompression to compare their accelerated aging. These composites were exposed to two accelerated xenon arc UV exposures where only the irradiance was modified. A multi-scale characterization was carried out to evaluate the consequences of the photooxidation on their mechanical and physicochemical properties with time. Results show that the photooxidation was limited to the surface. In addition, the photo-degradation of the surfaces of both composites was identified by the appearance of cracks, the variation of crystallinity, the decrease in weight average molar mass, and the appearance of new chemical products. These physicochemical variations are more evident with increasing irradiance. Despite these variations, the mechanical tensile properties of recycled matrix composites remain relatively indifferent to the two UV exposures compared to those with virgin polypropylene. It can be concluded that recycled polypropylene, if well selected, can replace virgin polypropylene in natural fiber composites for better mechanical resistance to photooxidation.
ISSN:0141-3910
1873-2321
DOI:10.1016/j.polymdegradstab.2023.110268