Your search keyword '"non-isothermal molecular dynamics simulations"' showing total 2 results

1. Coarse Graining Nonisothermal Microswimmer Suspensions

Author

Sven Auschra, Dipanjan Chakraborty, Gianmaria Falasco, Richard Pfaller, and Klaus Kroy

Subjects

homogenisation, active particles, microswimmers, hot brownian motion, non-isothermal molecular dynamics simulations, Physics, QC1-999

Abstract

We investigate coarse-grained models of suspended self-thermophoretic microswimmers. Upon heating, the Janus spheres, with hemispheres made of different materials, induce a heterogeneous local solvent temperature that causes the self-phoretic particle propulsion. Starting from molecular dynamics simulations that schematically resolve the molecular composition of the solvent and the microswimmer, we verify the coarse-grained description of the fluid in terms of a local molecular temperature field, and its role for the particle’s thermophoretic self-propulsion and hot Brownian motion. The latter is governed by effective nonequilibrium temperatures, which are measured from simulations by confining the particle position and orientation. They are theoretically shown to remain relevant for any further spatial coarse-graining towards a hydrodynamic description of the entire suspension as a homogeneous complex fluid.

Published

2021

2. Coarse Graining Nonisothermal Microswimmer Suspensions

Author

Auschra, Sven, Chakraborty, Dipanjan, Falasco, Gianmaria, Pfaller, Richard, and Kroy, Klaus

Subjects

homogenisation, active particles, homogenisation, active particles, microswimmers, hot brownian motion, non-isothermal molecular dynamics simulations, non-isothermal molecular dynamics simulations, Physics, QC1-999, Soft Condensed Matter (cond-mat.soft), FOS: Physical sciences, ddc:530, hot brownian motion, Condensed Matter - Soft Condensed Matter, microswimmers

Abstract

We investigate coarse-grained models of suspended self-thermophoretic microswimmers. Upon heating, the Janus spheres, with hemispheres made of different materials, induce a heterogeneous local solvent temperature that causes the self-phoretic particle propulsion. Starting from atomistic molecular dynamics simulations, we verify the coarse-grained description of the fluid in terms of a local molecular temperature field, and its role for the particle's thermophoretic self-propulsion and hot Brownian motion. The latter is governed by effective nonequilibrium temperatures, which are measured from simulations by confining the particle position and orientation. They are theoretically shown to remain relevant for any further spatial coarse-graining towards a hydrodynamic description of the entire suspension as a homogeneous complex fluid., Comment: 20 pages, 5 figures

Published

2021