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Related Concept Videos

Fatigue01:21

Fatigue

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Fatigue occurs when materials rupture under repeated or fluctuating loads, even at stress levels far below their static breaking strength. It typically results in brittle failure, even for ductile materials. It is a critical consideration in designing machines and structural components subjected to repetitive or varying loads. The nature of these loadings can range from fluctuating loads like unbalanced pump impellers causing vibrations to repeatedly bending a thin steel rod wire back and forth...
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Updated: Apr 24, 2026

Full-field Strain Measurements for Microstructurally Small Fatigue Crack Propagation Using Digital Image Correlation Method
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Parametrically upscaled model-based predictive platform for fatigue with location-specific microstructural linkages.

Somnath Ghosh1, Kishore Appunhi Nair2, Tawqeer Nasir Tak2

  • 1Civil & Systems Engineering, Johns Hopkins University, Baltimore, MD, USA. sghosh20@jhu.edu.

Nature Communications
|April 22, 2026
PubMed
Summary
This summary is machine-generated.

Predicting component dwell fatigue is challenging. This study introduces a computational platform integrating physics and machine learning to accurately forecast fatigue crack nucleation, linking microstructure to component life for better material design.

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Area of Science:

  • Materials Science
  • Mechanical Engineering
  • Computational Mechanics

Background:

  • Dwell fatigue in metallic materials, especially titanium alloys like Ti-6Al-4V, presents a significant engineering challenge due to unpredictable crack nucleation under cyclic loading with hold times.
  • Microstructural heterogeneity, including texture and anisotropic properties, critically influences fatigue crack evolution and life prediction.

Purpose of the Study:

  • To develop a spatiotemporal multiscale computational platform for predicting probabilistic dwell fatigue crack nucleation at the component scale.
  • To link location-specific microstructural features to fatigue crack initiation and propagation behavior.

Main Methods:

  • Integration of physics-based modeling, machine learning, temporal acceleration, and probabilistic analysis.
  • Development of parametrically upscaled constitutive and crack nucleation models (PUCM-PUCNM) for efficient multiscale predictions.
  • Experimental validation of the computational platform for nucleation studies.

Main Results:

  • The developed platform accurately predicts probabilistic fatigue crack nucleation, considering geometry and microstructure interactions under loading.
  • Demonstrated effectiveness of specimen test data-calibrated PUCM-PUCNMs for component-level fatigue predictions.
  • Successful exploration of competing effects of geometry and microstructure on fatigue crack evolution.

Conclusions:

  • The computational platform shows significant promise for multiscale fatigue predictions in metallic materials.
  • The approach enables a deeper understanding of microstructure-dependent fatigue crack nucleation mechanisms.
  • This work supports the design of fatigue-resistant structures and materials through accurate predictive modeling.