Numerical Study on the Dependency of Microstructure Morphologies of Pulsed Laser Deposited TiN Thin Films and the Strain Heterogeneities during Mechanical Testing

• Published in: Materials Vol. 14; no. 7; p. 1705
• Main Authors: Perzynski, Konrad, Cios, Grzegorz, Szwachta, Grzegorz, Bała, Piotr, Madej, Lukasz
• Format: Journal Article
• Language: English
• Published: Switzerland MDPI AG 30.03.2021; MDPI
• Subjects: Ablation; Algorithms; Atoms & subatomic particles; Computer simulation; digital material representation; Energy; Finite element method; kinetic Monte Carlo; Lasers; Mathematical models; Mechanical tests; Microstructure; Morphology; Nanoindentation; Probability; Pulsed laser deposition; Pulsed lasers; Representations; Strain; Thin films; digital material representation; pulsed laser deposition; kinetic Monte Carlo; thin films
• ISSN: 1996-1944; 1996-1944
• DOI: 10.3390/ma14071705

Numerical study of the influence of pulsed laser deposited TiN thin films' microstructure morphologies on strain heterogeneities during loading was the goal of this research. The investigation was based on the digital material representation (DMR) concept applied to replicate an investigated thin film's microstructure morphology. The physically based pulsed laser deposited model was implemented to recreate characteristic features of a thin film microstructure. The kinetic Monte Carlo (kMC) approach was the basis of the model in the first part of the work. The developed kMC algorithm was used to generate thin film's three-dimensional representation with its columnar morphology. Such a digital model was then validated with the experimental data from metallographic analysis of laboratory deposited TiN(100)/Si. In the second part of the research, the kMC generated DMR model of thin film was incorporated into the finite element (FE) simulation. The 3D film's morphology was discretized with conforming finite element mesh, and then incorporated as a microscale model into the macroscale finite element simulation of nanoindentation test. Such a multiscale model was finally used to evaluate the development of local deformation heterogeneities associated with the underlying microstructure morphology. In this part, the capabilities of the proposed approach were clearly highlighted.