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Macro- and micro-mechanical perspectives on creep-fatigue interaction in Type 316L stainless steel

Macro- and micro-mechanical perspectives on creep-fatigue interaction in Type 316L stainless steel
Macro- and micro-mechanical perspectives on creep-fatigue interaction in Type 316L stainless steel
Creep-fatigue of Type 316L stainless steel under asymmetric waveforms (specifically slow tension-fast compression, S-F, and fast tension-slow compression, F-S) has been understudied, despite its significant implications as demonstrated in this work. This study bridges macro- and micro-mechanical perspectives through a combined approach, involving high-temperature testing, scanning electron microscopy, X-ray computed tomography, neutron diffraction, and crystal plasticity modelling. Macro-mechanical tests revealed distinct deformation behaviours under S-F and F-S waveforms with and without a 1-hour tensile dwell at 550 °C, with S-F reducing lifespan in both fatigue and creep-fatigue conditions. Post-mortem analyses revealed distinct fracture morphologies induced by tensile dwell, with creep-fatigue S-F specimen exhibiting more pronounced intergranular-dominant fracture and higher internal defect volume. It also exhibited the highest number fraction of medium-sized (10–40 μm) microcracks, which correlates with its shortest fatigue life and more creep damage accumulation. Higher grain-level deformation incompatibility was observed during tensile dwell in the S-F load waveform. Crystal plasticity modelling revealed that the higher tensile stress amplitudes during S-F loading stem from increased dislocation density, with average densities at peak tensile strain during the saturation cycle reaching 186 μm⁻² for S-F and 147 μm⁻² for F-S waveforms. These findings establish a strong link between macroscopic and microscopic behaviours under asymmetric loading, emphasising the potential of S-F waveforms for cost-effective creep-fatigue experiment design. Furthermore, for the asymmetric waveforms studied, creep-fatigue life assessment using the ductility exhaustion method demonstrates greater accuracy than those based on the time fraction method.
Asymmetric load waveform, Austenitic steels, Creep-fatigue interaction, Crystal plasticity modelling, Deformation, Lattice strain, Neutron diffraction
0022-5096
Wu, Fan
af423be7-a614-4154-800e-67acbe790540
Liu, Yang
cf92e685-94b9-4317-b40e-606474ec98bf
Zhang, Huayue
becacff9-8f12-44c6-89d5-12de35ded9d0
Skamniotis, Christos
ae833674-6790-4618-b926-15f6822d37c4
Chaudry, Umer Masood
378b9b68-4e84-49b0-a6a2-6f45483bdd71
Douglas, Gareth
97df6de5-55db-4eb6-878c-2bbde8189253
Kelleher, Joe
e31434bd-e168-478d-a850-bb573806b768
Wisbey, Andrew
f25e12a6-59ab-43f3-8cfb-84a6f96e2926
Spindler, Mike
e3d2bba4-713f-4ce7-8357-08044678876f
Chevalier, Marc
d3a39cdb-6461-4040-8d71-ef55311baba3
Chen, Bo
be54a9a8-da2a-4e6f-ae0e-0b076be87daf
Wu, Fan
af423be7-a614-4154-800e-67acbe790540
Liu, Yang
cf92e685-94b9-4317-b40e-606474ec98bf
Zhang, Huayue
becacff9-8f12-44c6-89d5-12de35ded9d0
Skamniotis, Christos
ae833674-6790-4618-b926-15f6822d37c4
Chaudry, Umer Masood
378b9b68-4e84-49b0-a6a2-6f45483bdd71
Douglas, Gareth
97df6de5-55db-4eb6-878c-2bbde8189253
Kelleher, Joe
e31434bd-e168-478d-a850-bb573806b768
Wisbey, Andrew
f25e12a6-59ab-43f3-8cfb-84a6f96e2926
Spindler, Mike
e3d2bba4-713f-4ce7-8357-08044678876f
Chevalier, Marc
d3a39cdb-6461-4040-8d71-ef55311baba3
Chen, Bo
be54a9a8-da2a-4e6f-ae0e-0b076be87daf

Wu, Fan, Liu, Yang, Zhang, Huayue, Skamniotis, Christos, Chaudry, Umer Masood, Douglas, Gareth, Kelleher, Joe, Wisbey, Andrew, Spindler, Mike, Chevalier, Marc and Chen, Bo (2025) Macro- and micro-mechanical perspectives on creep-fatigue interaction in Type 316L stainless steel. Journal of the Mechanics and Physics of Solids, 206 (Part A), [106353]. (doi:10.1016/j.jmps.2025.106353).

Record type: Article

Abstract

Creep-fatigue of Type 316L stainless steel under asymmetric waveforms (specifically slow tension-fast compression, S-F, and fast tension-slow compression, F-S) has been understudied, despite its significant implications as demonstrated in this work. This study bridges macro- and micro-mechanical perspectives through a combined approach, involving high-temperature testing, scanning electron microscopy, X-ray computed tomography, neutron diffraction, and crystal plasticity modelling. Macro-mechanical tests revealed distinct deformation behaviours under S-F and F-S waveforms with and without a 1-hour tensile dwell at 550 °C, with S-F reducing lifespan in both fatigue and creep-fatigue conditions. Post-mortem analyses revealed distinct fracture morphologies induced by tensile dwell, with creep-fatigue S-F specimen exhibiting more pronounced intergranular-dominant fracture and higher internal defect volume. It also exhibited the highest number fraction of medium-sized (10–40 μm) microcracks, which correlates with its shortest fatigue life and more creep damage accumulation. Higher grain-level deformation incompatibility was observed during tensile dwell in the S-F load waveform. Crystal plasticity modelling revealed that the higher tensile stress amplitudes during S-F loading stem from increased dislocation density, with average densities at peak tensile strain during the saturation cycle reaching 186 μm⁻² for S-F and 147 μm⁻² for F-S waveforms. These findings establish a strong link between macroscopic and microscopic behaviours under asymmetric loading, emphasising the potential of S-F waveforms for cost-effective creep-fatigue experiment design. Furthermore, for the asymmetric waveforms studied, creep-fatigue life assessment using the ductility exhaustion method demonstrates greater accuracy than those based on the time fraction method.

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Accepted/In Press date: 7 September 2025
e-pub ahead of print date: 8 September 2025
Published date: 12 September 2025
Keywords: Asymmetric load waveform, Austenitic steels, Creep-fatigue interaction, Crystal plasticity modelling, Deformation, Lattice strain, Neutron diffraction

Identifiers

Local EPrints ID: 508258
URI: http://eprints.soton.ac.uk/id/eprint/508258
DOI: doi:10.1016/j.jmps.2025.106353
ISSN: 0022-5096
PURE UUID: a4e5c188-89ee-40b8-9c54-f07540022a38
ORCID for Bo Chen: ORCID iD orcid.org/0000-0003-1960-080X

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Date deposited: 15 Jan 2026 17:46
Last modified: 16 Jan 2026 03:08

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Contributors

Author: Fan Wu
Author: Yang Liu
Author: Huayue Zhang
Author: Christos Skamniotis
Author: Umer Masood Chaudry
Author: Gareth Douglas
Author: Joe Kelleher
Author: Andrew Wisbey
Author: Mike Spindler
Author: Marc Chevalier
Author: Bo Chen ORCID iD

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