Correlating fibre break development with fibre misalignment and resin-rich pockets using in situ holotomography
Correlating fibre break development with fibre misalignment and resin-rich pockets using in situ holotomography
Understanding the mechanical influence of microstructural variations on fibre break development is crucial for reducing uncertainties in predicting the longitudinal tensile failure of unidirectional composites. In this study, the interaction between local microstructural variations and fibre breaks is monitored using in situ X-ray holotomography at 150 nm voxel size. Three distinctive microstructures are identified to drive the initiation and clustering of breaks. First, misplaced fibres within the 0°/0° interply region, exhibiting significant misorientation and intersecting multiple aligned fibres, progressively trigger multiple single breaks and a co-planar cluster at their intersections. Second, resin-rich pockets within the 0°/0° interply region influence break clustering, progressively forming a non-coplanar cluster of five breaks, accompanied by non-uniform matrix microcracks and short interfacial debonds surrounding the clusters. Third, large resin-rich pockets, locally formed in regions with misoriented fibre groups, play a critical role in driving pronounced break clustering. Their interactions exhibit severe matrix nonlinearity, as evidenced by matrix microcracks, short interfacial debonds, and damage features, including microvoids or the onset of matrix microcracks. The identified fibre break patterns, clustering behaviour, and damage associated with three microstructural cases provide new insights into how these microstructures serve as precursors to fibre break development, highlighting the importance of accounting for them in predicting longitudinal tensile failure to improve reliability.
Polymer-matrix composites (PMCs), Microstructural variations, Fibre breaks, Synchrotron Holotomography
Lee, Yeajin
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Chatziathanasiou, Thanasis
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Breite, Christian
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Mehdikhani, Mahoor
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Swolfs, Yentl
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Mavrogordato, Mark
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Spearing, S.Mark
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Sinclair, Ian
6005f6c1-f478-434e-a52d-d310c18ade0d
21 October 2025
Lee, Yeajin
68771a14-4343-4e99-9837-832b10b6b5e7
Chatziathanasiou, Thanasis
9254adf2-338b-43de-8192-bb4c4af0f10e
Breite, Christian
c8c39a72-d72e-40c4-867e-ee5d391c084b
Mehdikhani, Mahoor
3b5c666f-4a46-43ed-be89-98af0794c1e8
Swolfs, Yentl
8fb273b4-39aa-45bc-b5b4-b8787793460a
Mavrogordato, Mark
f3e0879b-118a-463a-a130-1c890e9ab547
Spearing, S.Mark
9e56a7b3-e0e8-47b1-a6b4-db676ed3c17a
Sinclair, Ian
6005f6c1-f478-434e-a52d-d310c18ade0d
Lee, Yeajin, Chatziathanasiou, Thanasis, Breite, Christian, Mehdikhani, Mahoor, Swolfs, Yentl, Mavrogordato, Mark, Spearing, S.Mark and Sinclair, Ian
(2025)
Correlating fibre break development with fibre misalignment and resin-rich pockets using in situ holotomography.
Composites Part A: Applied Science and Manufacturing, 200 (109361), [109361].
(doi:10.1016/j.compositesa.2025.109361).
Abstract
Understanding the mechanical influence of microstructural variations on fibre break development is crucial for reducing uncertainties in predicting the longitudinal tensile failure of unidirectional composites. In this study, the interaction between local microstructural variations and fibre breaks is monitored using in situ X-ray holotomography at 150 nm voxel size. Three distinctive microstructures are identified to drive the initiation and clustering of breaks. First, misplaced fibres within the 0°/0° interply region, exhibiting significant misorientation and intersecting multiple aligned fibres, progressively trigger multiple single breaks and a co-planar cluster at their intersections. Second, resin-rich pockets within the 0°/0° interply region influence break clustering, progressively forming a non-coplanar cluster of five breaks, accompanied by non-uniform matrix microcracks and short interfacial debonds surrounding the clusters. Third, large resin-rich pockets, locally formed in regions with misoriented fibre groups, play a critical role in driving pronounced break clustering. Their interactions exhibit severe matrix nonlinearity, as evidenced by matrix microcracks, short interfacial debonds, and damage features, including microvoids or the onset of matrix microcracks. The identified fibre break patterns, clustering behaviour, and damage associated with three microstructural cases provide new insights into how these microstructures serve as precursors to fibre break development, highlighting the importance of accounting for them in predicting longitudinal tensile failure to improve reliability.
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More information
Accepted/In Press date: 14 August 2025
e-pub ahead of print date: 15 October 2025
Published date: 21 October 2025
Keywords:
Polymer-matrix composites (PMCs), Microstructural variations, Fibre breaks, Synchrotron Holotomography
Identifiers
Local EPrints ID: 506375
URI: http://eprints.soton.ac.uk/id/eprint/506375
ISSN: 1359-835X
PURE UUID: b4b5392b-e7af-4344-afb4-e1263b5dfa48
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Date deposited: 05 Nov 2025 17:41
Last modified: 06 Nov 2025 02:39
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Contributors
Author:
Yeajin Lee
Author:
Thanasis Chatziathanasiou
Author:
Christian Breite
Author:
Mahoor Mehdikhani
Author:
Yentl Swolfs
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