Non linear homogenization approach of strength of nanoporous materials with interface effects
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Publication:1621814
DOI10.1016/j.ijengsci.2013.04.006zbMath1423.74798OpenAlexW2070586129MaRDI QIDQ1621814
Publication date: 12 November 2018
Published in: International Journal of Engineering Science (Search for Journal in Brave)
Full work available at URL: https://doi.org/10.1016/j.ijengsci.2013.04.006
ductile behaviornanoporousspherical voidsinterfacial strengthmodified secant methodvoids size effects
Effective constitutive equations in solid mechanics (74Q15) Composite and mixture properties (74E30) Micromechanical theories (74A60)
Related Items (6)
Mathematical modeling of structural and near-surface non-homogeneities in thermoelastic thin films ⋮ Strength properties of nanoporous materials: a 3-layered based non-linear homogenization approach with interface effects ⋮ Prediction of forming limits for porous materials using void-size dependent model and bifurcation approach ⋮ Homogenization of elastic materials containing self-similar rigid micro-inclusions ⋮ On the strength of nanoporous materials with the account of surface effects ⋮ An embedded-FEM approach accounting for the size effect in nanocomposites
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- Size-Dependent Eshelby’s Tensor for Embedded Nano-Inclusions Incorporating Surface/Interface Energies
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