Buckling of functionally graded hydrogen-functionalized graphene reinforced beams based on machine learning-assisted micromechanics models
Created by W.Langdon from
gp-bibliography.bib Revision:1.8081
- @Article{ZHAO:2022:euromechsol,
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author = "Shaoyu Zhao and Yingyan Zhang and Yihe Zhang and
Wei Zhang and Jie Yang and Sritawat Kitipornchai",
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title = "Buckling of functionally graded
hydrogen-functionalized graphene reinforced beams based
on machine learning-assisted micromechanics models",
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journal = "European Journal of Mechanics - A/Solids",
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volume = "96",
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pages = "104675",
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year = "2022",
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ISSN = "0997-7538",
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DOI = "doi:10.1016/j.euromechsol.2022.104675",
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URL = "https://www.sciencedirect.com/science/article/pii/S0997753822001346",
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keywords = "genetic algorithms, genetic programming,
Graphene/metal nanocomposite, Hydrogen
functionalization, Functionally graded beam, Buckling,
Halpin-tsai model, Rule of mixture",
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abstract = "Nanocomposite reinforced with functionalized graphene
is a novel class of high-performance materials with
great potential in developing advanced lightweight
structures in a wide range of engineering applications.
However, accurate estimation of its material properties
at different temperature conditions remains a great
challenge as existing micromechanics models fail to
capture the effects of chemical functionalization and
temperature. This paper develops machine learning
(ML)-assisted micromechanics models by employing
genetic programming (GP) algorithm and molecular
dynamics (MD) simulation to address this key scientific
problem. The well-trained ML-assisted Halpin-Tsai model
and rule of mixture can accurately and efficiently
predict the temperature-dependent material properties
including Young's modulus, Poisson's ratio, coefficient
of thermal expansion (CTE), and density of
hydrogen-functionalized graphene (HFGr) reinforced
copper nanocomposites with high coefficients of
determination (R2). Then, the buckling behavior of
functionally graded (FG) HFGr nanocomposite beams is
studied with the aid of the ML-assisted micromechanics
models. A detailed parametric study is performed with a
particular focus on the effects of hydrogenation
percentage, graphene content, and temperature on the
buckling performance of the FG-HFGr beam. Results show
that bonding more hydrogen functional groups on the
HFGr can effectively improve the buckling resistance of
the beam",
- }
Genetic Programming entries for
Shaoyu Zhao
Yingyan Zhang
Yihe Zhang
Wei Zhang
Jie Yang
Sritawat Kitipornchai
Citations