Creep-fatigue crack growth behavior under mean stress effect in polymer electrolyte membrane: Experimental analysis and numerical crack growth modeling

Liang Cai; Wei Li; Pilin Song; Ibrahim Elbugdady; Gang Liu; Zhenduo Sun

doi:10.1016/j.engfracmech.2024.110789

Creep-fatigue crack growth behavior under mean stress effect in polymer electrolyte membrane: Experimental analysis and numerical crack growth modeling

Liang Cai, Wei Li^*, Pilin Song, Ibrahim Elbugdady, Gang Liu, Zhenduo Sun

^*此作品的通讯作者

科研成果: 期刊稿件 › 文章 › 同行评审

摘要

The creep-fatigue crack growth behavior of polymer electrolyte membrane under cyclic loading with distinct mean stress is investigated. The crack under cyclic loading with higher mean stress displays enhanced propagation rate. Identical cyclic plastic zone size is found under different stress ratios, implying that the fatigue damage primarily depends on stress amplitude. The creep damage leads to the occurrence of crack-front micropores, thereby accelerating crack growth. The enlargement of hydrophobic domain is detected at high stress ratio, which reveals the creep effect on failure process from phase morphology aspect. A damage-based numerical model is established to predict creep-fatigue crack growth.

源语言	英语
文章编号	110789
期刊	Engineering Fracture Mechanics
卷	314
DOI	https://doi.org/10.1016/j.engfracmech.2024.110789
出版状态	已出版 - 7 2月 2025

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10.1016/j.engfracmech.2024.110789

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Cai, L., Li, W., Song, P., Elbugdady, I., Liu, G., & Sun, Z. (2025). Creep-fatigue crack growth behavior under mean stress effect in polymer electrolyte membrane: Experimental analysis and numerical crack growth modeling. Engineering Fracture Mechanics, 314, 文章 110789. https://doi.org/10.1016/j.engfracmech.2024.110789

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title = "Creep-fatigue crack growth behavior under mean stress effect in polymer electrolyte membrane: Experimental analysis and numerical crack growth modeling",

abstract = "The creep-fatigue crack growth behavior of polymer electrolyte membrane under cyclic loading with distinct mean stress is investigated. The crack under cyclic loading with higher mean stress displays enhanced propagation rate. Identical cyclic plastic zone size is found under different stress ratios, implying that the fatigue damage primarily depends on stress amplitude. The creep damage leads to the occurrence of crack-front micropores, thereby accelerating crack growth. The enlargement of hydrophobic domain is detected at high stress ratio, which reveals the creep effect on failure process from phase morphology aspect. A damage-based numerical model is established to predict creep-fatigue crack growth.",

keywords = "Creep and fatigue, Damage-based model, Elastic-viscoplastic, In-situ, Mean stress",

author = "Liang Cai and Wei Li and Pilin Song and Ibrahim Elbugdady and Gang Liu and Zhenduo Sun",

note = "Publisher Copyright: {\textcopyright} 2024 Elsevier Ltd",

year = "2025",

month = feb,

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doi = "10.1016/j.engfracmech.2024.110789",

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AU - Li, Wei

AU - Song, Pilin

AU - Elbugdady, Ibrahim

AU - Liu, Gang

AU - Sun, Zhenduo

PY - 2025/2/7

Y1 - 2025/2/7

N2 - The creep-fatigue crack growth behavior of polymer electrolyte membrane under cyclic loading with distinct mean stress is investigated. The crack under cyclic loading with higher mean stress displays enhanced propagation rate. Identical cyclic plastic zone size is found under different stress ratios, implying that the fatigue damage primarily depends on stress amplitude. The creep damage leads to the occurrence of crack-front micropores, thereby accelerating crack growth. The enlargement of hydrophobic domain is detected at high stress ratio, which reveals the creep effect on failure process from phase morphology aspect. A damage-based numerical model is established to predict creep-fatigue crack growth.

AB - The creep-fatigue crack growth behavior of polymer electrolyte membrane under cyclic loading with distinct mean stress is investigated. The crack under cyclic loading with higher mean stress displays enhanced propagation rate. Identical cyclic plastic zone size is found under different stress ratios, implying that the fatigue damage primarily depends on stress amplitude. The creep damage leads to the occurrence of crack-front micropores, thereby accelerating crack growth. The enlargement of hydrophobic domain is detected at high stress ratio, which reveals the creep effect on failure process from phase morphology aspect. A damage-based numerical model is established to predict creep-fatigue crack growth.

KW - Creep and fatigue

KW - Damage-based model

KW - Elastic-viscoplastic

KW - In-situ

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Creep-fatigue crack growth behavior under mean stress effect in polymer electrolyte membrane: Experimental analysis and numerical crack growth modeling

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