Abstract
This study investigates the capacity of the nano-indentation method in the mechanical characterization of a heterogeneous dental restorative nanocomposite using experimental and computational approaches. In this respect, Filtek Z350 XT was selected as a nano-particle reinforced polymer nanocomposite with a specific range of the particle size (50 nm to 4 µm), within the range of indenter contact area of the nano-indentation experiment. A Sufficient number of nano-indentation tests were performed in various locations of the nanocomposite to extract the hardness and elastic modulus properties. A hybrid computational-experimental approach was developed to examine the extracted properties by linking the internal behaviour and the global response of the nanocomposite. In the computational part, several representative models of the nanocomposite were created in a finite element environment to simulate the mechanism of elastic-plastic deformation of the nanocomposite under Berkovich indenter. Dispersed values of hardness and elastic modulus were obtained through the experiment with 26.8 and 48.5 percent average errors, respectively, in comparison to the nanocomposite properties, respectively. A disordered shape was predicted for plastic deformation of the equilateral indentation mark, representing the interaction of the particles and matrix, which caused the experiment results reflect the local behaviour of the nanocomposite instead of the real material properties.
Highlights
A computational-experimental approach is required to link the finite element (FE) simulation and experiment data in order to develop a valid FE model, in which the data are used to describe the disperse response of the material that led to calculation of different mechanical properties
The experiment and the finite element (FE) simulation results are described in terms of the global response of the nanocomposite as load-displacement curves and mechanical properties, and the internal behaviour of the nanocomposites in the form of deformation and plastic strain
The existence of any damage or crack around the indentation impression may cause the values of hardness and elastic modulus obtained from the nano-indentation test, do not represent the mechanical www.nature.com/scientificreports properties of the sample material
Summary
A computational-experimental approach is required to link the FE simulation and experiment data in order to develop a valid FE model, in which the data are used to describe the disperse response of the material that led to calculation of different mechanical properties. The existence of any damage or crack around the indentation impression may cause the values of hardness and elastic modulus obtained from the nano-indentation test, do not represent the mechanical www.nature.com/scientificreports properties of the sample material.
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