Your search keyword '"Ostanin, Igor"' showing total 3 results

1. Atomistic mechanism of friction force independence on the normal load and other friction laws for dynamic structural superlubricity

Author

Brilliantov, Nikolay V., Tsukanov, Alexey A., Grebenko, Artem K., Nasibulin, Albert G., and Ostanin, Igor A.

Subjects

Physics - Computational Physics, Condensed Matter - Soft Condensed Matter

Abstract

We explore dynamic structural superlubricity for the case of a relatively large contact area, where the friction force is proportional to the area (exceeding $\sim 100\,nm^2$) experimentally, numerically, and theoretically. We use a setup comprised of two molecular smooth incommensurate surfaces -- graphene-covered tip and substrate. The experiments and MD simulations demonstrate independence of the friction force on the normal load, for a wide range of normal loads and relative surface velocities. We propose an atomistic mechanism of this phenomenon, associated with synchronic out-of-plane surface fluctuations of thermal origin, and confirm it by numerical experiments. Based on this mechanism, we develop a theory for this type of superlubricity and show that friction force increases linearly with increasing temperature and relative velocity, for velocities, larger than a threshold velocity. The MD results are in a fair agreement with predictions of the theory., Comment: Accepted to Physical Review Letters on November 14, 2023

Published

2023

2. Collapse modes in SC and BCC arrangements of elastic beads

Author

Ostanin, Igor A., Oganov, Artem R., and Magnanimo, Vanessa

Subjects

Condensed Matter - Soft Condensed Matter, Condensed Matter - Materials Science

Abstract

Collapse modes in compressed simple cubic (SC) and body-centered cubic (BCC) periodic arrangements of elastic frictionless beads were studied numerically using the discrete element method. Under pure hydrostatic compression, the SC arrangement tends to transform into a defective hexagonal close-packed or amorphous structure. The BCC assembly exhibits several modes of collapse, one of which, identified as cI16 structure, is consistent with the behavior of BCC metals Li and Na under high pressure. The presence of a deviatoric stress leads to the transformation of the BCC structure into face-centered cubic (FCC) one via the Bain path. The observed effects provide important insights on the origins of mechanical behavior of atomic systems, while the elastic spheres model used in our work can become a useful paradigm, expanding the capabilities of a hard sphere model widely used in many branches of science.

Published

2020

3. High-Performance Numerical Modeling of Nanofabrics with Distinct Element Method

Author

Ostanin, Igor A.

Subjects

Physics - Computational Physics, Condensed Matter - Soft Condensed Matter

Abstract

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.

Published

2019