Is stored energy density the primary meso-scale mechanistic driver for fatigue crack nucleation? Int J Plast 2018;101:213 –29

Chen B, Jiang J, Dunne FPE · 2018 · DOI 10.1016/j.ijplas.2017.11.005

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In situ elucidation of mechanisms governing crack transition to plasticity arrest

cond-mat.mtrl-sci · 2025-10-04 · unverdicted · novelty 7.0

In situ SEM-DIC and EBSD measurements on cold-worked AA-5052 show crack arrest coincides with divergence of elastic and elastoplastic energy release rates as the crack-tip process zone expands beyond grain size.

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In situ elucidation of mechanisms governing crack transition to plasticity arrest cond-mat.mtrl-sci · 2025-10-04 · unverdicted · none · ref 16
In situ SEM-DIC and EBSD measurements on cold-worked AA-5052 show crack arrest coincides with divergence of elastic and elastoplastic energy release rates as the crack-tip process zone expands beyond grain size.

Is stored energy density the primary meso-scale mechanistic driver for fatigue crack nucleation? Int J Plast 2018;101:213 –29

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