Artificial thermal shock cracks in WRe – A proof of concept study

Research output: Contribution to journalArticleResearchpeer-review

Standard

Artificial thermal shock cracks in WRe – A proof of concept study. / Sommerauer, Michael; Siller, Maximilian; Pippan, Reinhard et al.
In: Nuclear Materials and Energy, Vol. 39.2024, No. June, 101685, 29.05.2024.

Research output: Contribution to journalArticleResearchpeer-review

Vancouver

Sommerauer M, Siller M, Pippan R, Bostrom N, Maier-Kiener V. Artificial thermal shock cracks in WRe – A proof of concept study. Nuclear Materials and Energy. 2024 May 29;39.2024(June):101685. Epub 2024 May 29. doi: 10.1016/j.nme.2024.101685

Bibtex - Download

@article{038ba35c34064e469c0cab6dd4213bef,
title = "Artificial thermal shock cracks in WRe – A proof of concept study",
abstract = "Thermal shock cracks are frequently observed in environments where extensive thermal cycling at high amplitudes is common. Typical cases for such are first wall materials in proposed fusion reactors and rotating anodes for computed tomography scanners. The formation of these cracks is driven by significant tensile stresses during the cooldown phase, following prior plastic deformation at elevated temperatures. This work proposes an experimental approach, where artificial thermal shock-like structures are generated via femtosecond laser ablation in WRe as a model material. Following a detailed laser parameter study in a W sheet material, patterns were introduced to WRe samples and investigated by different microscopy techniques. Their morphology as well as their response to thermo-cyclic loads was investigated and compared to conventionally induced thermal shock cracks. The introduction of artificial cracks by femtosecond laser ablation that mimic the morphology and behaviour of naturally induced thermal shock cracks is feasible within certain boundaries. Cuts, comparable to thermal shock cracks in width and depth, can be ablated. The cuts show an effect on the surrounding microstructure in line with the thermal shock cracks. Therefore, comparability could be proven concerning morphological and microstructural aspects. The conducted thermo-cyclic fatigue tests revealed an analogous effect on subsequent damage accumulation between the thermal shock cracks induced by thermal loading and artificial laser ablated cuts, proving the comparability under dynamic loading conditions. The extent of the effect is adjustable by tailoring the geometry of the lasered structures. The presented work suggests the possibility of studying the influence of thermal shock cracks on further fatigue mechanisms in exceptionally demanding applications, such as first wall materials or rotating anodes, by practical experimentation. Based on the resulting in-depth understanding of underlying interactions, the lifetime of these components might be prolonged by a deliberate introduction of crack networks or laser-ablated structures.",
keywords = "Fatigue Testing, Femtosecond Laser Ablation, High-Temperature Electron Scanning Microscopy, In-situ Damage Acquisition, Thermal Expansion, Thermal Shock Cracking",
author = "Michael Sommerauer and Maximilian Siller and Reinhard Pippan and Neil Bostrom and Verena Maier-Kiener",
note = "Publisher Copyright: {\textcopyright} 2024 The Author(s)",
year = "2024",
month = may,
day = "29",
doi = "10.1016/j.nme.2024.101685",
language = "English",
volume = "39.2024",
journal = "Nuclear Materials and Energy",
issn = "2352-1791",
publisher = "Elsevier",
number = "June",

}

RIS (suitable for import to EndNote) - Download

TY - JOUR

T1 - Artificial thermal shock cracks in WRe – A proof of concept study

AU - Sommerauer, Michael

AU - Siller, Maximilian

AU - Pippan, Reinhard

AU - Bostrom, Neil

AU - Maier-Kiener, Verena

N1 - Publisher Copyright: © 2024 The Author(s)

PY - 2024/5/29

Y1 - 2024/5/29

N2 - Thermal shock cracks are frequently observed in environments where extensive thermal cycling at high amplitudes is common. Typical cases for such are first wall materials in proposed fusion reactors and rotating anodes for computed tomography scanners. The formation of these cracks is driven by significant tensile stresses during the cooldown phase, following prior plastic deformation at elevated temperatures. This work proposes an experimental approach, where artificial thermal shock-like structures are generated via femtosecond laser ablation in WRe as a model material. Following a detailed laser parameter study in a W sheet material, patterns were introduced to WRe samples and investigated by different microscopy techniques. Their morphology as well as their response to thermo-cyclic loads was investigated and compared to conventionally induced thermal shock cracks. The introduction of artificial cracks by femtosecond laser ablation that mimic the morphology and behaviour of naturally induced thermal shock cracks is feasible within certain boundaries. Cuts, comparable to thermal shock cracks in width and depth, can be ablated. The cuts show an effect on the surrounding microstructure in line with the thermal shock cracks. Therefore, comparability could be proven concerning morphological and microstructural aspects. The conducted thermo-cyclic fatigue tests revealed an analogous effect on subsequent damage accumulation between the thermal shock cracks induced by thermal loading and artificial laser ablated cuts, proving the comparability under dynamic loading conditions. The extent of the effect is adjustable by tailoring the geometry of the lasered structures. The presented work suggests the possibility of studying the influence of thermal shock cracks on further fatigue mechanisms in exceptionally demanding applications, such as first wall materials or rotating anodes, by practical experimentation. Based on the resulting in-depth understanding of underlying interactions, the lifetime of these components might be prolonged by a deliberate introduction of crack networks or laser-ablated structures.

AB - Thermal shock cracks are frequently observed in environments where extensive thermal cycling at high amplitudes is common. Typical cases for such are first wall materials in proposed fusion reactors and rotating anodes for computed tomography scanners. The formation of these cracks is driven by significant tensile stresses during the cooldown phase, following prior plastic deformation at elevated temperatures. This work proposes an experimental approach, where artificial thermal shock-like structures are generated via femtosecond laser ablation in WRe as a model material. Following a detailed laser parameter study in a W sheet material, patterns were introduced to WRe samples and investigated by different microscopy techniques. Their morphology as well as their response to thermo-cyclic loads was investigated and compared to conventionally induced thermal shock cracks. The introduction of artificial cracks by femtosecond laser ablation that mimic the morphology and behaviour of naturally induced thermal shock cracks is feasible within certain boundaries. Cuts, comparable to thermal shock cracks in width and depth, can be ablated. The cuts show an effect on the surrounding microstructure in line with the thermal shock cracks. Therefore, comparability could be proven concerning morphological and microstructural aspects. The conducted thermo-cyclic fatigue tests revealed an analogous effect on subsequent damage accumulation between the thermal shock cracks induced by thermal loading and artificial laser ablated cuts, proving the comparability under dynamic loading conditions. The extent of the effect is adjustable by tailoring the geometry of the lasered structures. The presented work suggests the possibility of studying the influence of thermal shock cracks on further fatigue mechanisms in exceptionally demanding applications, such as first wall materials or rotating anodes, by practical experimentation. Based on the resulting in-depth understanding of underlying interactions, the lifetime of these components might be prolonged by a deliberate introduction of crack networks or laser-ablated structures.

KW - Fatigue Testing

KW - Femtosecond Laser Ablation

KW - High-Temperature Electron Scanning Microscopy

KW - In-situ Damage Acquisition

KW - Thermal Expansion

KW - Thermal Shock Cracking

UR - http://www.scopus.com/inward/record.url?scp=85194743276&partnerID=8YFLogxK

U2 - 10.1016/j.nme.2024.101685

DO - 10.1016/j.nme.2024.101685

M3 - Article

VL - 39.2024

JO - Nuclear Materials and Energy

JF - Nuclear Materials and Energy

SN - 2352-1791

IS - June

M1 - 101685

ER -