Details
Original language | English |
---|---|
Article number | 115393 |
Number of pages | 1 |
Journal | Composite structures |
Volume | 289 |
Early online date | 12 Mar 2022 |
Publication status | Published - 1 Jun 2022 |
Abstract
Based on a stochastic full-range multiscale model, we propose a data-driven approach to predict the thermal conductivity of CNT reinforced polymeric nano-composites (PNCs). Uncertain input parameters at different scales are propagated from nano- to macro-scale within a bottom-up multi-scale framework. Atomistic models are employed at the nano-scale while continuum mechanics approaches are used at the micro-, meso- and macro-scale. Representative volume elements in the context of finite element modeling (RVE-FEM) are used to finally obtain the homogenized thermal conductivity. To connect the micro and mesoscale and simplify the computation, we take advantage of the equivalent fiber theory. The input parameters are selected by a top-down scanning method and subsequently are converted as uncertain inputs. The length of single-walled carbon nanotube (SWCNT), the chirality of SWCNT, the thermal conductivity of the fibers, the thermal conductivity of the matrix, the Kapitza resistance, aspect ratio, agglomeration index, dispersion index and volume fraction are assumed as random-parameters. The Regression-tree-based (Random Forest and Gradient Boosting Machine) and Neural networks-based (Artificial neural networks and Deep neural networks) approaches are exploited for computational efficiency, where Particle Swarm Optimization (PSO) and 10-fold Cross Validation (CV) are employed for hyper-parameter tuning. Our machine learning prediction results agree well with published experimental data, which can provide a versatile and efficient method to design new PNCs.
Keywords
- Data-driven modeling (DDM), Machine Learning, Polymeric Nanotube composites (PNCs), Stochastic multi-scale modeling, Thermal properties
ASJC Scopus subject areas
- Materials Science(all)
- Ceramics and Composites
- Engineering(all)
- Civil and Structural Engineering
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In: Composite structures, Vol. 289, 115393, 01.06.2022.
Research output: Contribution to journal › Article › Research › peer review
}
TY - JOUR
T1 - Stochastic full-range multiscale modeling of thermal conductivity of Polymeric carbon nanotubes composites
T2 - A machine learning approach
AU - Liu, Bokai
AU - Vu-Bac, Nam
AU - Fu, Xiaolong
AU - Zhuang, Xiaoying
AU - Rabczuk, Timon
N1 - Funding Information: We gratefully acknowledge the support of the China Scholarship Council (CSC) .
PY - 2022/6/1
Y1 - 2022/6/1
N2 - Based on a stochastic full-range multiscale model, we propose a data-driven approach to predict the thermal conductivity of CNT reinforced polymeric nano-composites (PNCs). Uncertain input parameters at different scales are propagated from nano- to macro-scale within a bottom-up multi-scale framework. Atomistic models are employed at the nano-scale while continuum mechanics approaches are used at the micro-, meso- and macro-scale. Representative volume elements in the context of finite element modeling (RVE-FEM) are used to finally obtain the homogenized thermal conductivity. To connect the micro and mesoscale and simplify the computation, we take advantage of the equivalent fiber theory. The input parameters are selected by a top-down scanning method and subsequently are converted as uncertain inputs. The length of single-walled carbon nanotube (SWCNT), the chirality of SWCNT, the thermal conductivity of the fibers, the thermal conductivity of the matrix, the Kapitza resistance, aspect ratio, agglomeration index, dispersion index and volume fraction are assumed as random-parameters. The Regression-tree-based (Random Forest and Gradient Boosting Machine) and Neural networks-based (Artificial neural networks and Deep neural networks) approaches are exploited for computational efficiency, where Particle Swarm Optimization (PSO) and 10-fold Cross Validation (CV) are employed for hyper-parameter tuning. Our machine learning prediction results agree well with published experimental data, which can provide a versatile and efficient method to design new PNCs.
AB - Based on a stochastic full-range multiscale model, we propose a data-driven approach to predict the thermal conductivity of CNT reinforced polymeric nano-composites (PNCs). Uncertain input parameters at different scales are propagated from nano- to macro-scale within a bottom-up multi-scale framework. Atomistic models are employed at the nano-scale while continuum mechanics approaches are used at the micro-, meso- and macro-scale. Representative volume elements in the context of finite element modeling (RVE-FEM) are used to finally obtain the homogenized thermal conductivity. To connect the micro and mesoscale and simplify the computation, we take advantage of the equivalent fiber theory. The input parameters are selected by a top-down scanning method and subsequently are converted as uncertain inputs. The length of single-walled carbon nanotube (SWCNT), the chirality of SWCNT, the thermal conductivity of the fibers, the thermal conductivity of the matrix, the Kapitza resistance, aspect ratio, agglomeration index, dispersion index and volume fraction are assumed as random-parameters. The Regression-tree-based (Random Forest and Gradient Boosting Machine) and Neural networks-based (Artificial neural networks and Deep neural networks) approaches are exploited for computational efficiency, where Particle Swarm Optimization (PSO) and 10-fold Cross Validation (CV) are employed for hyper-parameter tuning. Our machine learning prediction results agree well with published experimental data, which can provide a versatile and efficient method to design new PNCs.
KW - Data-driven modeling (DDM)
KW - Machine Learning
KW - Polymeric Nanotube composites (PNCs)
KW - Stochastic multi-scale modeling
KW - Thermal properties
UR - http://www.scopus.com/inward/record.url?scp=85126582297&partnerID=8YFLogxK
U2 - 10.1016/j.compstruct.2022.115393
DO - 10.1016/j.compstruct.2022.115393
M3 - Article
VL - 289
JO - Composite structures
JF - Composite structures
SN - 0263-8223
M1 - 115393
ER -