Identification of the elastic-plastic properties of CrN coating on elastic-plastic substrate by nanoindentation using finite element method-reverse algorithm

• Published in: Thin solid films Vol. 756; p. 139356
• Main Authors: Ben Ammar, Y., Aouadi, Khalil, Nouveau, Corinne, Besnard, Aurélien, Montagne, Alex
• Format: Journal Article
• Language: English
• Published: Elsevier B.V 31.08.2022; Elsevier
• Subjects: Composite hardness modeling; Elasto-plastic properties; Engineering Sciences; Film/substrate system; Instrumented-indentation testing; Inverse finite element material modelling; Mechanics; Mechanics of materials; Substrate effect; Film/substrate system; Elasto-plastic properties; Inverse finite element material modelling; Substrate effect; Instrumented-indentation testing; Composite hardness modeling
• ISSN: 0040-6090; 1879-2731; 1879-2731
• DOI: 10.1016/j.tsf.2022.139356

•Nanoindentation of CrN coatings deposited at different substrate bias voltages.•A trust-region algorithm is used to predict the tensile properties of the coating.•The uniqueness issue is addressed by narrowing the range of the initial guess.•The stress-strains coating characteristics were accurately generated. This paper proposes an identification methodology based on nanoindentation analysis of coating/substrate system to extract the elastic-plastic properties of coating materials on elastic-plastic substrate when the indenter penetration depth is greater than the film thickness. In order to accurately predict the elastic-plastic properties of the coating materials, a trust-region reflective optimization algorithm is integrated with the finite element analysis, in cooperation with the Jönsson and Hogmark model. The proposed reverse analysis algorithm modifies a predicted load-displacement (P-h) curve by changing the elastic-plastic properties of the coating and the substrate until it fits the experimental nanoindentation (P-h) curve. Numerical and instrumental indentations tests were carried out on a CrN film/Martensitic stainless steel substrate system to verify the proposed reverse method, by which Young's modulus (E), yield stress (σy), and work hardening exponent of the film were obtained. A sensitivity analysis is conducted to study the effect of the elastic-plastic properties of the CrN film/substrate on the (P-h) curve. The results showed a high impact to the loading and unloading part of the (P-h) curve due to variations in (E) and (σy) of the steel substrate compared to those of the CrN coating.