Deformation mechanisms at the tip of internal fatigue cracks in vacuum and in the presence of an air environment in a Ti alloy

Ultrasonic fully reversed tension fatigue tests have been performed in the Very High Cycle Fatigue (VHCF) regime (NR>107−108cycles) on Ti-6Al4V specimens containing a controlled internal notch. Two sets of samples have been used. The first one contains a central chimney along the specimen longitu...

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Published in:International journal of fatigue 2025-04, Vol.193, p.108729, Article 108729
Main Authors: Hébrard, Louis, Palin-Luc, Thierry, Ranc, Nicolas, Weck, Arnaud, Douillard, Thierry, Blanchard, Nicholas, Dancette, Sylvain, Buffiere, Jean-Yves
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Language:English
Subjects:
Environment
Internal fatigue cracks
Nanograin
Ti-6Al-4V
Twining
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container_title International journal of fatigue
container_volume 193
creator Hébrard, Louis
Palin-Luc, Thierry
Ranc, Nicolas
Weck, Arnaud
Douillard, Thierry
Blanchard, Nicholas
Dancette, Sylvain
Buffiere, Jean-Yves
description Ultrasonic fully reversed tension fatigue tests have been performed in the Very High Cycle Fatigue (VHCF) regime (NR>107−108cycles) on Ti-6Al4V specimens containing a controlled internal notch. Two sets of samples have been used. The first one contains a central chimney along the specimen longitudinal axis which brings air to the internal notch; in the second series the notches are not connected to the surface. The microstructure present below the fracture surface of the broken specimens has been studied by electron microscopy (EBSD, TKD and TEM). The formation of nanograins and nanovoids was observed below the surface of the cracks growing in a vacuum environment but not below the surface of cracks connected with ambient air. In the latter case extensive striations were observed. Below each striation the formation of tensile {101̄2} twins was observed. •Fatigue samples with sharp internal defects with or without connection with air are tested.•Growth mechanisms of internal cracks are observed with or without air at the crack tip.•Striation marks are observed on the internal crack surfaces propagating in air.•No striation marks are observed on the internal crack surfaces growing in vacuum.•Twins are observed below the striations for the cracks growing in air.
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subjects Environment
Internal fatigue cracks
Nanograin
Ti-6Al-4V
Twining
title Deformation mechanisms at the tip of internal fatigue cracks in vacuum and in the presence of an air environment in a Ti alloy
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