Unified decomposition method to study Rayleigh-Taylor instability in liquids and solids

Y. B. Sun; J. J. Tao; X. T. He

doi:10.1103/PhysRevE.97.063109

Unified decomposition method to study Rayleigh-Taylor instability in liquids and solids

Y. B. Sun, J. J. Tao, X. T. He

Peking University

Research output: Contribution to journal › Article › peer-review

14 Citations (Scopus)

Abstract

In the previous studies of Rayleigh-Taylor instability, different methods were used to consider the effects of elasticity, viscosity, and magnetic fields. In this paper, a unified method, which was first used for fluids, is validated for different physical models, where the unstable mode is decomposed into an irrotational part and a rotational part, and the latter one includes the effects of nonconservative forces and constitutive relations. Previous results of solid and liquid with or without the effects of magnetic fields and finite thickness can be easily recovered after applying the corresponding interface boundary conditions. In addition, new approximate but analytical solutions of the growth rates for a semi-infinite solid-solid interface and solid-fluid interface are obtained with substantially improved accuracy in comparison with the previous ones.

Original language	English
Article number	063109
Journal	Physical Review E
Volume	97
Issue number	6
DOIs	https://doi.org/10.1103/PhysRevE.97.063109
Publication status	Published - 19 Jun 2018
Externally published	Yes

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title = "Unified decomposition method to study Rayleigh-Taylor instability in liquids and solids",

abstract = "In the previous studies of Rayleigh-Taylor instability, different methods were used to consider the effects of elasticity, viscosity, and magnetic fields. In this paper, a unified method, which was first used for fluids, is validated for different physical models, where the unstable mode is decomposed into an irrotational part and a rotational part, and the latter one includes the effects of nonconservative forces and constitutive relations. Previous results of solid and liquid with or without the effects of magnetic fields and finite thickness can be easily recovered after applying the corresponding interface boundary conditions. In addition, new approximate but analytical solutions of the growth rates for a semi-infinite solid-solid interface and solid-fluid interface are obtained with substantially improved accuracy in comparison with the previous ones.",

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AU - He, X. T.

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AB - In the previous studies of Rayleigh-Taylor instability, different methods were used to consider the effects of elasticity, viscosity, and magnetic fields. In this paper, a unified method, which was first used for fluids, is validated for different physical models, where the unstable mode is decomposed into an irrotational part and a rotational part, and the latter one includes the effects of nonconservative forces and constitutive relations. Previous results of solid and liquid with or without the effects of magnetic fields and finite thickness can be easily recovered after applying the corresponding interface boundary conditions. In addition, new approximate but analytical solutions of the growth rates for a semi-infinite solid-solid interface and solid-fluid interface are obtained with substantially improved accuracy in comparison with the previous ones.

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Unified decomposition method to study Rayleigh-Taylor instability in liquids and solids

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