Effects of particles size on the overall strength of nanocomposites: Molecular Dynamics simulations and theoretical modeling

Antoine Lucchetta; Stella Brach; Djimédo Kondo

doi:10.1016/j.mechrescom.2021.103669

Effects of particles size on the overall strength of nanocomposites: Molecular Dynamics simulations and theoretical modeling

Antoine Lucchetta
, Stella Brach
, Djimédo Kondo

Sorbonne Université

Research output: Contribution to journal › Article › peer-review

Abstract

We perform Molecular Dynamics simulations to investigate the strength properties of particulate reinforced nanocomposites. For a fixed reinforcement volume fraction, the effective strength increases as the inclusion size decreases. We further develop a kinematic limit analysis approach, which delivers theoretical estimates of the effective strength. The model is first assessed in the absence of size effects by comparison with data from available literature. An extension to nanocomposites is then proposed, accounting for the presence of surface stresses at the matrix/inclusion interface. Numerical data are used to calibrate the interfacial strength, which is found to be a size-dependent property.

Original language	English
Article number	103669
Journal	Mechanics Research Communications
Volume	114
DOIs	https://doi.org/10.1016/j.mechrescom.2021.103669
Publication status	Published - 1 Jun 2021

Keywords

Limit analysis
Molecular Dynamics computations
Nanocomposites
Strength properties

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10.1016/j.mechrescom.2021.103669

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title = "Effects of particles size on the overall strength of nanocomposites: Molecular Dynamics simulations and theoretical modeling",

abstract = "We perform Molecular Dynamics simulations to investigate the strength properties of particulate reinforced nanocomposites. For a fixed reinforcement volume fraction, the effective strength increases as the inclusion size decreases. We further develop a kinematic limit analysis approach, which delivers theoretical estimates of the effective strength. The model is first assessed in the absence of size effects by comparison with data from available literature. An extension to nanocomposites is then proposed, accounting for the presence of surface stresses at the matrix/inclusion interface. Numerical data are used to calibrate the interfacial strength, which is found to be a size-dependent property.",

keywords = "Limit analysis, Molecular Dynamics computations, Nanocomposites, Strength properties",

author = "Antoine Lucchetta and Stella Brach and Djim{\'e}do Kondo",

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year = "2021",

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T1 - Effects of particles size on the overall strength of nanocomposites

T2 - Molecular Dynamics simulations and theoretical modeling

AU - Lucchetta, Antoine

AU - Brach, Stella

AU - Kondo, Djimédo

PY - 2021/6/1

Y1 - 2021/6/1

N2 - We perform Molecular Dynamics simulations to investigate the strength properties of particulate reinforced nanocomposites. For a fixed reinforcement volume fraction, the effective strength increases as the inclusion size decreases. We further develop a kinematic limit analysis approach, which delivers theoretical estimates of the effective strength. The model is first assessed in the absence of size effects by comparison with data from available literature. An extension to nanocomposites is then proposed, accounting for the presence of surface stresses at the matrix/inclusion interface. Numerical data are used to calibrate the interfacial strength, which is found to be a size-dependent property.

AB - We perform Molecular Dynamics simulations to investigate the strength properties of particulate reinforced nanocomposites. For a fixed reinforcement volume fraction, the effective strength increases as the inclusion size decreases. We further develop a kinematic limit analysis approach, which delivers theoretical estimates of the effective strength. The model is first assessed in the absence of size effects by comparison with data from available literature. An extension to nanocomposites is then proposed, accounting for the presence of surface stresses at the matrix/inclusion interface. Numerical data are used to calibrate the interfacial strength, which is found to be a size-dependent property.

KW - Limit analysis

KW - Molecular Dynamics computations

KW - Nanocomposites

KW - Strength properties

UR - https://www.scopus.com/pages/publications/85103707958

U2 - 10.1016/j.mechrescom.2021.103669

DO - 10.1016/j.mechrescom.2021.103669

M3 - Article

AN - SCOPUS:85103707958

SN - 0093-6413

VL - 114

JO - Mechanics Research Communications

JF - Mechanics Research Communications

M1 - 103669

ER -

Effects of particles size on the overall strength of nanocomposites: Molecular Dynamics simulations and theoretical modeling

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Keywords

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