Unravelling the Distinctive Effects of Hydrogen and Vacancies on Elastic and Plastic Properties in Ni<100> Using Nanoindentation: Some Progress on Antagonist Hardening and Softening Effects

45 Pages Posted: 30 Apr 2025

See all articles by Siva Prasad Murugan

Siva Prasad Murugan

La Rochelle University - LaSIE CNRS UMR 7356

Yasmine Ben Jedidia

affiliation not provided to SSRN

Abdelali Oudriss

affiliation not provided to SSRN

Xavier Feaugas

University of Paris-Saclay - Service de la Corrosion et du Comportement des Matériaux dans leur Environnement (SCCME)

Abstract

One of the fundamental aspects of hydrogen embrittlement is based on the impacts of hydrogen on the elementary mechanisms of plasticity. Even though it is well known that the solute hydrogen generally deteriorates the ductility of nickel, it highlighted the existence of antagonistic processes in the hydrogen effect as well, i.e., hydrogen-induced hardening and/or softening without a relevant universal explanation. These effects may also reflect an implication of hydrogen on the modification of the elasticity properties. In this work, the impact of hydrogen on elastic modulus, dislocation nucleation (i.e., pop-in), and hardness was investigated in nickel <100> single crystal using nanoindentation. The evolution of the different properties during hydrogen desorption offers the opportunity to distinguish the direct impact of hydrogen from those associated with solute-induced defects. The deformed sub-surfaces by nanoindentation were analyzed by TEM to characterise the development of dislocation structures and any other defects, and hence to establish the hydrogen-defect-elasticity-plasticity correlations. Hertz’s theory was used to model the elastic regime and Oliver and Pharr's model (Oliver and Pharr, 1992) was used to analyze the elastoplastic regime of the nanoindentation load-displacement curve. Hydrogen-induced impacts on maximum shear stress to activate dislocations, hardness and elastic modulus were observed. An irreversible reduction in elastic modulus with hydrogen absorption revealed the influence of hydrogen-induced vacancy clusters on elasticity. In addition, the increase in pop-in load and hardness with hydrogen absorption indicated a hardening behavior in the plastic regime, resulting from the interaction of interstitial hydrogen and vacancy clusters with dislocation nucleation and mobility.

Keywords: Hydrogen embrittlement, nickel, Nanoindentation, elasticity, Plasticity, dislocation nucleation, vacancy clusters

Suggested Citation

Murugan, Siva Prasad and Ben Jedidia, Yasmine and Oudriss, Abdelali and Feaugas, Xavier, Unravelling the Distinctive Effects of Hydrogen and Vacancies on Elastic and Plastic Properties in Ni<100> Using Nanoindentation: Some Progress on Antagonist Hardening and Softening Effects. Available at SSRN: https://ssrn.com/abstract=5237456 or http://dx.doi.org/10.2139/ssrn.5237456

Siva Prasad Murugan

La Rochelle University - LaSIE CNRS UMR 7356 ( email )

Yasmine Ben Jedidia

affiliation not provided to SSRN ( email )

Abdelali Oudriss (Contact Author)

affiliation not provided to SSRN ( email )

Xavier Feaugas

University of Paris-Saclay - Service de la Corrosion et du Comportement des Matériaux dans leur Environnement (SCCME) ( email )

France

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