A Supervised Machine Learning Approach for Accelerating the Design of
Particulate Composites: Application to Thermal Conductivity
- URL: http://arxiv.org/abs/2010.00041v3
- Date: Tue, 5 Jan 2021 02:15:23 GMT
- Title: A Supervised Machine Learning Approach for Accelerating the Design of
Particulate Composites: Application to Thermal Conductivity
- Authors: Mohammad Saber Hashemi, Masoud Safdari, Azadeh Sheidaei
- Abstract summary: A supervised machine learning (ML) based computational methodology for the design of particulate multifunctional composite materials is presented.
Design variables are physical descriptors of the material microstructure that directly link microstructure to the material's properties.
Our optimized ML method is trained over the generated database and establishes the complex relationship between the structure and properties.
- Score: 0.0
- License: http://arxiv.org/licenses/nonexclusive-distrib/1.0/
- Abstract: A supervised machine learning (ML) based computational methodology for the
design of particulate multifunctional composite materials with desired thermal
conductivity (TC) is presented. The design variables are physical descriptors
of the material microstructure that directly link microstructure to the
material's properties. A sufficiently large and uniformly sampled database was
generated based on the Sobol sequence. Microstructures were realized using an
efficient dense packing algorithm, and the TCs were obtained using our
previously developed Fast Fourier Transform (FFT) homogenization method. Our
optimized ML method is trained over the generated database and establishes the
complex relationship between the structure and properties. Finally, the
application of the trained ML model in the inverse design of a new class of
composite materials, liquid metal (LM) elastomer, with desired TC is discussed.
The results show that the surrogate model is accurate in predicting the
microstructure behavior with respect to high-fidelity FFT simulations, and
inverse design is robust in finding microstructure parameters according to case
studies.
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