Multiscale Modeling of Thermoplastics Using Atomistic-Informed Micromechanics

Authors

Evan J. Pineda, NASA Glenn Research Center
Jamal F. Husseini, Francis College of Engineering
Josh Kemppainen, Michigan Technological UniversityFollow
Brett A. Bednarcyk, NASA Glenn Research Center
William A. Pisani, Environmental Laboratory
Gregory Odegard, Michigan Technological UniversityFollow
Scott E. Stapleton, Francis College of Engineering

Document Type

Article

Publication Date

6-2025

Department

Department of Mechanical and Aerospace Engineering

Abstract

A multiscale repeating unit cell model of a single spherulite containing four disparate length scales was developed to predict the thermoelastic behavior of semicrystalline thermoplastic materials for composite aerospace applications. The continuum level scales were fully coupled and modeled using the generalized method of cells and the high-fidelity generalized method of cells micromechanics theories. Data from molecular dynamics simulations were used as inputs for the amorphous and crystalline constituents in the multiscale continuum models. Effective Young’s modulus, shear modulus, Poisson’s ratio, coefficient of thermal expansion, and thermal conductivity were predicted for polyether ether ketone and polyether ketone ketone, showing good agreement with the available experimental data from the open literature. Moreover, it is shown that predicted properties are fairly insensitive to the fidelity of the micromechanics model used at the highest continuum scale or the assumed shape of the spherulite.

Publication Title

AIAA Journal

Recommended Citation

Pineda, E., Husseini, J., Kemppainen, J., Bednarcyk, B., Pisani, W., Odegard, G., & Stapleton, S. (2025). Multiscale Modeling of Thermoplastics Using Atomistic-Informed Micromechanics. AIAA Journal, 63(6), 2373-2381. http://doi.org/10.2514/1.J065054
Retrieved from: https://digitalcommons.mtu.edu/michigantech-p2/1781