Research team reveals surprising findings on cyclic material fatigue in amorphous materials

Past the breaking point
Researchers at The University of Tokyo simulated fractures in amorphous materials due to both cyclic fatigue and constant stress using course-grained dynamics, and demonstrated various failure modes, which can help improve reliability of materials. Credit: Institute of Industrial Science, The University of Tokyo

Researchers at The University of Tokyo have shown that for amorphous materials, cyclic material fatigue can begin to fracture at the same level of stress as fractures due to constant loading. By using computer simulations, the team was able to distinguish four distinct failure modes. This work could improve the lifetime of industrial machinery.

Damage to industrial parts is expensive, results in delays, and may be unsafe to plant workers. But now, the scientists from Japan have simulated fracture initiated in materials that share a particular physical characteristic and are widely used across domestic, industrial and scientific applications. Their work, published in Communications Materials, showed surprising results that may help prevent damage to industrial parts.

If you’ve ever been bored in a meeting and tried playing with a metal paperclip to pass the time, you may have noticed something surprising. Although the paperclip starts flexible and returns to its original shape several times, it may suddenly snap after enough cycles. This is an example of “fatigue,” in which cracks and defects build up as an object is subjected to cyclic loading and unloading of stress. Material fatigue is a significant concern in many industrial applications, and especially for machine or airplane parts that experience many cycles of stress, and for which a sudden failure could be catastrophic. As a result, obtaining a better understanding of the underlying process of material fatigue could yield significant benefits, especially for non-crystalline materials.

The team of researchers at the Institute of Industrial Science, The University of Tokyo, studied the physical mechanisms of low-cycle fatigue fracture in the case of amorphous solids, such as glass or plastics, using computer simulations. For crystalline materials, it has been shown that pre-existing defects and grain boundaries can initiate a fracture because of fatigue.

However, the corresponding mechanism in amorphous materials is not well understood. While it seems intuitive that the stress required for a fracture to occur is much smaller for cyclic stresses compared with constant stress, this was not what the scientists found. “Contrary to the common belief, we showed that the critical strain in disorder materials that corresponds with the onset of irreversible deformation is the same for both fatigue and monotonic fractures,” says co-author Yuji Kurotani.

This is because for ordinary amorphous systems, higher density leads to more elasticity and slower dynamics. This density dependence of mechanical properties couples the shear deformation with density fluctuations. The cyclic shear can then amplify density fluctuations until the sample breaks via cavitation, in which voids are produced.

“This situation is like a crowded train,” says co-author Hajime Tanaka. “Dynamic and elastic asymmetries with respect to density changes can lead to a link between shear deformation and density fluctuations.” These authors mention that these results should be confirmed with experiments, which would also help material scientists better understand the initiation of fractures.


Deformation fingerprints will help researchers identify, design better metallic materials


More information:
Fatigue fracture mechanism of amorphous materials from a density-based coarse-grained model, Communications Materials (2022). DOI: 10.1038/s43246-022-00293-9

Provided by
University of Tokyo


Citation:
Research team reveals surprising findings on cyclic material fatigue in amorphous materials (2022, October 11)
retrieved 11 October 2022
from https://phys.org/news/2022-10-team-reveals-cyclic-material-fatigue.html

This document is subject to copyright. Apart from any fair dealing for the purpose of private study or research, no
part may be reproduced without the written permission. The content is provided for information purposes only.

For all the latest Science News Click Here 

 For the latest news and updates, follow us on Google News

Read original article here

Denial of responsibility! TheDailyCheck is an automatic aggregator around the global media. All the content are available free on Internet. We have just arranged it in one platform for educational purpose only. In each content, the hyperlink to the primary source is specified. All trademarks belong to their rightful owners, all materials to their authors. If you are the owner of the content and do not want us to publish your materials on our website, please contact us by email – [email protected] The content will be deleted within 24 hours.