Molecular dynamics study of rotating nanodroplets: Finite-size effects and nonequilibrium deformation

Hiroshi Watanabe; Naoki Mitsuda; Tomoaki Nogawa; Nobuyasu Ito

doi:10.1088/1742-6596/297/1/012023

Molecular dynamics study of rotating nanodroplets: Finite-size effects and nonequilibrium deformation

Hiroshi Watanabe, Naoki Mitsuda, Tomoaki Nogawa, Nobuyasu Ito

Research output: Contribution to journal › Conference article › peer-review

1 Citation (Scopus)

Abstract

Noneqiuilibrium dynamics of rotating droplets are studied by molecular dynamics simulations. Small deviations from the theoretical prediction are observed when the size of a droplet is small, and the deviations become smaller as the size of the droplet increases. The characteristic timescale of the deformation is observed, and we find (i) the deformation timescale is almost independent of the rotating velocity with for small frequency and (ii) the deformation timescale becomes shorter as temperature increases. A simple model is proposed to explain the deformation dynamics of droplets.

Original language	English
Article number	012023
Journal	Journal of Physics: Conference Series
Volume	297
Issue number	1
DOIs	https://doi.org/10.1088/1742-6596/297/1/012023
Publication status	Published - 2011
Externally published	Yes
Event	7th International Conferences on Statistical Physics, STATPHYS-Kolkata VII - Kolkata, India Duration: 2010 Nov 26 → 2010 Nov 30

ASJC Scopus subject areas

Physics and Astronomy(all)

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title = "Molecular dynamics study of rotating nanodroplets: Finite-size effects and nonequilibrium deformation",

abstract = "Noneqiuilibrium dynamics of rotating droplets are studied by molecular dynamics simulations. Small deviations from the theoretical prediction are observed when the size of a droplet is small, and the deviations become smaller as the size of the droplet increases. The characteristic timescale of the deformation is observed, and we find (i) the deformation timescale is almost independent of the rotating velocity with for small frequency and (ii) the deformation timescale becomes shorter as temperature increases. A simple model is proposed to explain the deformation dynamics of droplets.",

author = "Hiroshi Watanabe and Naoki Mitsuda and Tomoaki Nogawa and Nobuyasu Ito",

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T2 - 7th International Conferences on Statistical Physics, STATPHYS-Kolkata VII

AU - Watanabe, Hiroshi

AU - Mitsuda, Naoki

AU - Nogawa, Tomoaki

AU - Ito, Nobuyasu

PY - 2011

Y1 - 2011

N2 - Noneqiuilibrium dynamics of rotating droplets are studied by molecular dynamics simulations. Small deviations from the theoretical prediction are observed when the size of a droplet is small, and the deviations become smaller as the size of the droplet increases. The characteristic timescale of the deformation is observed, and we find (i) the deformation timescale is almost independent of the rotating velocity with for small frequency and (ii) the deformation timescale becomes shorter as temperature increases. A simple model is proposed to explain the deformation dynamics of droplets.

AB - Noneqiuilibrium dynamics of rotating droplets are studied by molecular dynamics simulations. Small deviations from the theoretical prediction are observed when the size of a droplet is small, and the deviations become smaller as the size of the droplet increases. The characteristic timescale of the deformation is observed, and we find (i) the deformation timescale is almost independent of the rotating velocity with for small frequency and (ii) the deformation timescale becomes shorter as temperature increases. A simple model is proposed to explain the deformation dynamics of droplets.

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JO - Journal of Physics: Conference Series

JF - Journal of Physics: Conference Series

IS - 1

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Y2 - 26 November 2010 through 30 November 2010

ER -

Molecular dynamics study of rotating nanodroplets: Finite-size effects and nonequilibrium deformation

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