On Rayleigh–Taylor Dynamics

Abdul Hasib Rahimyar; Des Hill; James Glimm; Snezhana Abarzhi

doi:10.3390/atoms11120155

On Rayleigh–Taylor Dynamics

Abdul Hasib Rahimyar, Des Hill, James Glimm, Snezhana Abarzhi

Mathematics and Statistics

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Abstract

In this work, we theoretically and numerically investigate Rayleigh–Taylor dynamics with constant acceleration. On the side of theory, we employ the group theory approach to directly link the governing equations to the momentum model, and to precisely derive the buoyancy and drag parameters for the bubble and spike in the linear, nonlinear, and mixing regimes. On the side of simulations, we analyze numerical data on Rayleigh–Taylor mixing by applying independent self-similar processes associated with the growth of the bubble amplitude and with the bubble merger. Based on the obtained results, we reveal the constituents governing Rayleigh–Taylor dynamics in the linear, nonlinear, and mixing regimes. We outline the implications of our considerations for experiments in plasmas, including inertial confinement fusion.

Original language	English
Article number	155
Journal	Atoms
Volume	11
Issue number	12
DOIs	https://doi.org/10.3390/atoms11120155
Publication status	Published - Dec 2023

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title = "On Rayleigh–Taylor Dynamics",

abstract = "In this work, we theoretically and numerically investigate Rayleigh–Taylor dynamics with constant acceleration. On the side of theory, we employ the group theory approach to directly link the governing equations to the momentum model, and to precisely derive the buoyancy and drag parameters for the bubble and spike in the linear, nonlinear, and mixing regimes. On the side of simulations, we analyze numerical data on Rayleigh–Taylor mixing by applying independent self-similar processes associated with the growth of the bubble amplitude and with the bubble merger. Based on the obtained results, we reveal the constituents governing Rayleigh–Taylor dynamics in the linear, nonlinear, and mixing regimes. We outline the implications of our considerations for experiments in plasmas, including inertial confinement fusion.",

keywords = "boundary value problems, inertial confinement fusion, Rayleigh–Taylor instabilities, self-similar mixing",

author = "Rahimyar, {Abdul Hasib} and Des Hill and James Glimm and Snezhana Abarzhi",

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doi = "10.3390/atoms11120155",

language = "English",

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journal = "Atoms",

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T1 - On Rayleigh–Taylor Dynamics

AU - Rahimyar, Abdul Hasib

AU - Hill, Des

AU - Glimm, James

AU - Abarzhi, Snezhana

PY - 2023/12

Y1 - 2023/12

N2 - In this work, we theoretically and numerically investigate Rayleigh–Taylor dynamics with constant acceleration. On the side of theory, we employ the group theory approach to directly link the governing equations to the momentum model, and to precisely derive the buoyancy and drag parameters for the bubble and spike in the linear, nonlinear, and mixing regimes. On the side of simulations, we analyze numerical data on Rayleigh–Taylor mixing by applying independent self-similar processes associated with the growth of the bubble amplitude and with the bubble merger. Based on the obtained results, we reveal the constituents governing Rayleigh–Taylor dynamics in the linear, nonlinear, and mixing regimes. We outline the implications of our considerations for experiments in plasmas, including inertial confinement fusion.

AB - In this work, we theoretically and numerically investigate Rayleigh–Taylor dynamics with constant acceleration. On the side of theory, we employ the group theory approach to directly link the governing equations to the momentum model, and to precisely derive the buoyancy and drag parameters for the bubble and spike in the linear, nonlinear, and mixing regimes. On the side of simulations, we analyze numerical data on Rayleigh–Taylor mixing by applying independent self-similar processes associated with the growth of the bubble amplitude and with the bubble merger. Based on the obtained results, we reveal the constituents governing Rayleigh–Taylor dynamics in the linear, nonlinear, and mixing regimes. We outline the implications of our considerations for experiments in plasmas, including inertial confinement fusion.

KW - boundary value problems

KW - inertial confinement fusion

KW - Rayleigh–Taylor instabilities

KW - self-similar mixing

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U2 - 10.3390/atoms11120155

DO - 10.3390/atoms11120155

M3 - Article

AN - SCOPUS:85180490123

VL - 11

JO - Atoms

JF - Atoms

IS - 12

M1 - 155

ER -

On Rayleigh–Taylor Dynamics

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