Material Class Fatigue: Critical Factors and Predictive Models
Received Date: Sep 01, 2025 / Published Date: Sep 29, 2025
Abstract
This compilation of research explores diverse aspects of material fatigue. Studies on high-strength steel emphasize mean stress effects and advanced modeling. Additively manufactured titanium alloys benefit from surface treatments to enhance fatigue life. Nickel-based superalloys face creep-fatigue interactions at elevated temperatures. Polymer composites’ fatigue performance is linked to fiber orientation. Powder metallurgy improves aluminum alloy fatigue strength. Railway axle steel fatigue prediction is enhanced by fracture mechanics. Welded steel joints are improved by post-weld treatments. Concrete fatigue is influenced by aggregate characteristics. Magnesium alloys’ fatigue crack initiation is studied via crystal plasticity modeling. Elevated temperatures accelerate crack growth in cast aluminum alloys due to creep-fatigue effects.
Citation: Clarke B (2025) Material Class Fatigue: Critical Factors and Predictive Models. jpmm 14: 501.
Copyright: 漏 2025 Benjamin Clarke This is an open-access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution and reproduction in any medium, provided the original author and source are credited.
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