Toward large scale modeling of carbon nanotube systems with the mesoscopic distinct element method

Ostanin, Igor; Zhilyaev, Petr; Petrov, V.; Dumitrică, Traian; Eibl, Sebastian; Ruede, Ulrich; Kuzkin, Vitaly A.

doi:10.22226/2410-3535-2018-3-240-245

Cited by 9 publications

(8 citation statements)

References 13 publications

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“…The key components (for the present investigation) of the two-body EVM potential U ij describe the resistance to stretching U t ij and bending U b ij deformation of the two elements, Fig. 1(b) right, as34,37…”

mentioning

confidence: 99%

Densification of single-walled carbon nanotube films: Mesoscopic distinct element method simulations and experimental validation

Drozdov

Ostanin

et al. 2020

Journal of Applied Physics

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Nanometer-thin single-walled carbon nanotube (CNT) films collected from the aerosol chemical deposition reactors have gathered attention for their promising applications. Densification of these pristine films provides an important way to manipulate mechanical, electronic, and optical properties. To elucidate the underlying microstructural level restructuring, which is ultimately responsible for the change in properties, we perform large scale vector-based mesoscopic distinct element method simulations in conjunction with electron microscopy and spectroscopic ellipsometry characterization of pristine and densified films by drop-cast volatile liquid processing. Matching with the microscopy observations, pristine CNT films with a finite thickness are modeled as self-assembled CNT networks comprising entangled dendritic bundles with branches extending down to individual CNTs. Simulations of these films under uniaxial compression uncover a soft deformation regime extending up to an ∼75% strain. When removing the loads, the pre-compressed samples evolve into homogeneously densified films with thickness values depending on both the pre-compression level and the sample microstructure. The significant reduction in thickness is attributed to the underlying structural changes occurring at the 100 nm scale, including the zipping of the thinnest dendritic branches.

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mentioning

confidence: 99%

Densification of single-walled carbon nanotube films: Mesoscopic distinct element method simulations and experimental validation

Drozdov

Ostanin

et al. 2020

Journal of Applied Physics

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“…The most important of them is absent torsional stiffness of fibrils leading to unrealistic behaviors of fibrillar assemblies under certain loadings. In order to solve this issue, a different discretization concept [12][13][14][15][16][17][18][19] was suggested using a representation of a thin fiber as a chain of rigid bodies, rather than point masses. Such a model allows not only bending of individual fibers, but their torsion as well.…”

Section: Introductionmentioning

confidence: 99%

“…Until now, the remaining obstacle on the route toward applications of MDEM to large-scale modeling of fibrillar assemblies was the absence of its scalable, parallel realization. Such realization has been recently suggested in [19]. It is based on rigid particle dynamics module of the waLBerla multiphysics framework [20].…”

Section: Introductionmentioning

confidence: 99%

Distinct Element Simulation of Mechanical Properties of Hypothetical CNT Nanofabrics

Ostanin

2019

JSFI

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A universal framework for modeling composites and fabrics of micro-and nanofibers, such as carbon nanotubes, carbon fibers and amyloid fibrils, is presented. Within this framework, fibers are represented with chains of rigid bodies, linked with elastic bonds. Elasticity of the bonds utilizes recently developed enhanced vector model formalism. The type of interactions between fibers is determined by their nature and physical length scale of the simulation. The dynamics of fibers is computed using the modification of rigid particle dynamics module of the waLBerla multiphysics framework. Our modeling system demonstrates exceptionally high parallel performance combined with the physical accuracy of the modeling. The efficiency of our technique is demonstrated with an illustrative mechanical test on a hypothetical carbon nanotube textile. In this example, the elasticity of the fibers represents the coarse-grained covalent bond within CNT surface, whereas interfiber interactions represent coarse-grained van der Waals forces between cylindrical segments of nanotubes. Numerical simulation demonstrates stability and extremal strength of a hypothetical carbon nanotube fabric.

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“…The most important of them is absent torsional stiffness of fibrils leading to unrealistic behaviors of fibrillar assemblies under certain loadings. In order to solve this issue, a different discretization concept [12,13,14,15,16,17,18,19] was suggested using a representation of a thin fiber as a chain of rigid bodies, rather than point masses. Such a model allows not only bending of individual fibers, but their torsion as well.…”

Section: Introductionmentioning

confidence: 99%

“…Until now, the remaining obstacle on the route toward applications of MDEM to large-scale modeling of fibrillar assemblies was the absence of its scalable, parallel realization. Such realization was recently suggested in [19]. It is based on rigid particle dynamics module of the waLBerla multiphysics framework [20].…”

Section: Introductionmentioning

confidence: 99%

High-Performance Numerical Modeling of Nanofabrics with Distinct Element Method

Ostanin

2019

Preprint

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A universal framework for modeling composites and fabrics of micro-and nanofibers, such as carbon nanotubes, carbon fibers and amyloid fibrils, is presented. Within this framework, fibers are represented with chains of rigid bodies, linked with elastic bonds. Elasticity of the bonds utilizes recently developed enhanced vector model formalism. The type of interactions between fibers is determined by their nature and physical length scale of the simulation. The dynamics of fibers is computed using the modification of rigid particle dynamics module of the waLBerla multiphysics framework. Our modeling system demonstrates exceptionally high parallel performance combined with the physical accuracy of the modeling. The efficiency of our approach is demonstrated with illustrative mechanical test on a hypothetical carbon nanotube textile.

show abstract

Toward large scale modeling of carbon nanotube systems with the mesoscopic distinct element method

Cited by 9 publications

References 13 publications

Densification of single-walled carbon nanotube films: Mesoscopic distinct element method simulations and experimental validation

Densification of single-walled carbon nanotube films: Mesoscopic distinct element method simulations and experimental validation

Distinct Element Simulation of Mechanical Properties of Hypothetical CNT Nanofabrics

High-Performance Numerical Modeling of Nanofabrics with Distinct Element Method

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