Concurrent multiscale modeling of three dimensional crack and dislocation propagation

Talebi, Hossein; Silani, Mohammad; Rabczuk, Timon

doi:10.1016/j.advengsoft.2014.09.016

Cited by 187 publications

(40 citation statements)

References 45 publications

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“…It should be mentioned that, except in the areas of direct contact between surfaces (where the effect of friction is modeled with the inclusion of some impacts), in the above equations, the viscous friction force f D i is uniformly applied to the atoms inside the IVs and UVs [27]. A same strategy could be observed in [28].…”

Section: Large-small Coupling Modelmentioning

confidence: 91%

Benchmarking the penetration-resistance efficiency of multilayer graphene sheets due to spacing the graphene layers

Sadeghzadeh

2016

Appl. Phys. A

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In this paper, the penetration-resistance efficiency of single-layer and multilayer graphene sheets has been investigated by means of the multiscale approach. The employed multiscale approach has been implemented by establishing a direct correlation between the finite element method and the molecular dynamics approach and validated by comparing its results with those of the existing experimental works. Since by using numerous techniques, a new class of graphene sheets can be fabricated in which the graphene layers are spaced farther apart (more than the usual distance between layers), this paper has concentrated on the optimal spacing between graphene layers with the goal of improving the impact properties of graphene sheets as important candidates for novel impact-resistant panels. For this purpose, the relative protection (protection with respect to weight) values of graphene sheets were obtained, and it was observed that the relative protection of a singlelayer graphene sheet is about 3.64 times that of a 20-layer graphene sheet. This study also showed that a spaced multilayer graphene sheet, with its inter-layer distance being 20 times the usual spacing between ordinary graphene layers, has an impact resistance which is about 20 % higher than that of an ordinary 20-layer graphene sheet. The findings of this paper can be appropriately used in the design and fabrication of future-generation impact-resistant protective panels.

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Section: Large-small Coupling Modelmentioning

confidence: 91%

Benchmarking the penetration-resistance efficiency of multilayer graphene sheets due to spacing the graphene layers

Sadeghzadeh

2016

Appl. Phys. A

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“…The coupling of molecular space to continuum domain is accomplished through bridging domain methods which can be recognized as the main challenge of these methods. Transferring structure‐property relations from molecular level to continuum level is considered as the most challenging issue in multi‐scale modeling of nanocomposites where it is necessary to conciliate encountered length and time scales over several orders of magnitudes . Recently, a multi‐scale model bridging length and time scales from molecular to continuum levels wherein nanoscale simulations obtained from MDs were homogenized to a continuum constitutive model for resin .…”

Section: Mechanical Properties Of Nanoclay/polymermentioning

confidence: 99%

Mechanical Properties of Nanoclay and Nanoclay Reinforced Polymers: A Review

Rafiee

Shahzadi

2018

Polymer Composites

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A literature review is conducted on performed investigations for characterizing Young's modulus of nanoclay platelet as the reinforcing agent of nanoclay/polymer nanocomposites from both experimental and theoretical aspects. The observed discrepancies in the reported results are discussed accordingly. All available investigations for predicting mechanical properties of nanoclay reinforced polymers are also reviewed. The employed methods in ongoing studies are categorized into three groups as atomistic, continuum and multiscale modeling techniques. Those challenging issues which are still in need of more accurate understanding and discussion are identified and outlined through a gap analysis on current investigations. The introduced shortcomings can be considered as prospective research areas for the future studies in the field of estimating mechanical properties of nanoclay based composites. POLYM. COMPOS., 40:431–445, 2019. © 2018 Society of Plastics Engineers

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“…Unfortunately, classical continuum theories cannot predict such complex behavior and more advanced methods should be adopted. Recently, several advanced computational methods such as meshfree [11][12][13][14][15] and multiscale methods were developed for fracture analysis [16,17] and crack propagation [18,19] in homogenous and heterogeneous materials. They estimated the material properties at the finer scales and used them as input parameters for the coarser one.…”

mentioning

confidence: 99%

Multiscale dynamic fracture behavior of the carbon nanotube reinforced concrete under impact loading

Eftekhari

Mohammadi

2016

International Journal of Impact Engineering

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Concurrent multiscale modeling of three dimensional crack and dislocation propagation

Cited by 187 publications

References 45 publications

Benchmarking the penetration-resistance efficiency of multilayer graphene sheets due to spacing the graphene layers

Benchmarking the penetration-resistance efficiency of multilayer graphene sheets due to spacing the graphene layers

Mechanical Properties of Nanoclay and Nanoclay Reinforced Polymers: A Review

Multiscale dynamic fracture behavior of the carbon nanotube reinforced concrete under impact loading

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