Nanomechanical inhomogeneities in CVA-deposited titanium nitride thin films: Nanoindentation and Finite Element Method Investigations

TL;DR

This study investigates the nanomechanical inhomogeneities of CVA-deposited titanium nitride thin films using nanoindentation and finite element modeling, revealing the impact of local nitridation on mechanical properties.

Contribution

It introduces a FEM-based approach to model nanoscale inhomogeneities in TiN thin films and highlights the role of nitrogen deficiency in their mechanical behavior.

Findings

Nitrogen deficient regions are more ductile with lower yield stress.

Nanoindentation reveals spatial fluctuations in nanomechanical properties.

FEM simulations confirm the influence of local nitridation on mechanical response.

Abstract

Refractory metals that can withstand at high temperatures and harsh conditions are of utmost importance for solar-thermal and energy storage applications. Thin films of TiN have been deposited using cathodic vacuum arc deposition (CVA) at relatively low temperatures ~ 300 oC using the substrate bias ~ -60V. The nanomechanical properties of these films were investigated using nanoindentation and the spatial fluctuations were observed. The nanoindentation results were simulated using finite element method (FEM) through Johnson-Cook model. We have found the local nitridation plays an important role on nanomechanical properties of TiN thin films and confirms that the nitrogen deficient regions are ductile with low yield stress and hardening modulus. This study further opens the opportunities of modelling the nanoscale system using FEM analysis.