Numerical prediction of interfacial instabilities: Sharp interface method (SIM)

We introduce a sharp interface method (SIM) for the direct numerical simulation of unstable fluid–fluid interfaces. The method is based on the level set approach and the structured adaptive mesh refinement technology, endowed with a corridor of irregular, cut-cell grids that resolve the interfacial...

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Veröffentlicht in:	Journal of computational physics 2008-04, Vol.227 (8), p.3940-3970
Hauptverfasser:	Nourgaliev, R.R., Liou, M.-S., Theofanous, T.G.
Format:	Artikel
Sprache:	eng
Schlagworte:	ALGORITHMS CLASSICAL AND QUANTUM MECHANICS, GENERAL PHYSICS Gas–liquid interfaces HELMHOLTZ INSTABILITY Instability-seeding in numerical simulations Interfacial flows Interfacial instability INTERPOLATION LEAST SQUARE FIT RANDOMNESS RAYLEIGH-TAYLOR INSTABILITY Sharp-interface treatment SIMULATION SURFACE FORCES Viscous Kelvin–Helmholtz instability Yih instability
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container_end_page	3970
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container_title	Journal of computational physics
container_volume	227
creator	Nourgaliev, R.R. Liou, M.-S. Theofanous, T.G.
description	We introduce a sharp interface method (SIM) for the direct numerical simulation of unstable fluid–fluid interfaces. The method is based on the level set approach and the structured adaptive mesh refinement technology, endowed with a corridor of irregular, cut-cell grids that resolve the interfacial region to third-order spatial accuracy. Key in that regard are avoidance of numerical mixing, and a least-squares interpolation method that is supported by irregular datasets distinctly on each side of the interface. Results on test problems show our method to be free of the spurious current problem of the continuous surface force method and to converge, on grid refinement, at near-theoretical rates. Simulations of unstable Rayleigh–Taylor and viscous Kelvin–Helmholtz flows are found to converge at near-theoretical rates to the exact results over a wide range of conditions. Further, we show predictions of neutral-stability maps of the viscous Kelvin–Helmholtz flows (Yih instability), as well as self-selection of the most unstable wave-number in multimode simulations of Rayleigh–Taylor instability. All these results were obtained with a simple seeding of random infinitesimal disturbances of interface-shape, as opposed to seeding by a complete eigenmode. For other than elementary flows the latter would normally not be available, and extremely difficult to obtain if at all. Sample comparisons with our code adapted to mimic typical diffuse interface treatments were not satisfactory for shear-dominated flows. On the other hand the sharp dynamics of our method would appear to be compatible and possibly advantageous to any interfacial flow algorithm in which the interface is represented as a discrete Heaviside function.
doi_str_mv	10.1016/j.jcp.2007.12.008
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The method is based on the level set approach and the structured adaptive mesh refinement technology, endowed with a corridor of irregular, cut-cell grids that resolve the interfacial region to third-order spatial accuracy. Key in that regard are avoidance of numerical mixing, and a least-squares interpolation method that is supported by irregular datasets distinctly on each side of the interface. Results on test problems show our method to be free of the spurious current problem of the continuous surface force method and to converge, on grid refinement, at near-theoretical rates. Simulations of unstable Rayleigh–Taylor and viscous Kelvin–Helmholtz flows are found to converge at near-theoretical rates to the exact results over a wide range of conditions. Further, we show predictions of neutral-stability maps of the viscous Kelvin–Helmholtz flows (Yih instability), as well as self-selection of the most unstable wave-number in multimode simulations of Rayleigh–Taylor instability. All these results were obtained with a simple seeding of random infinitesimal disturbances of interface-shape, as opposed to seeding by a complete eigenmode. For other than elementary flows the latter would normally not be available, and extremely difficult to obtain if at all. Sample comparisons with our code adapted to mimic typical diffuse interface treatments were not satisfactory for shear-dominated flows. 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The method is based on the level set approach and the structured adaptive mesh refinement technology, endowed with a corridor of irregular, cut-cell grids that resolve the interfacial region to third-order spatial accuracy. Key in that regard are avoidance of numerical mixing, and a least-squares interpolation method that is supported by irregular datasets distinctly on each side of the interface. Results on test problems show our method to be free of the spurious current problem of the continuous surface force method and to converge, on grid refinement, at near-theoretical rates. Simulations of unstable Rayleigh–Taylor and viscous Kelvin–Helmholtz flows are found to converge at near-theoretical rates to the exact results over a wide range of conditions. Further, we show predictions of neutral-stability maps of the viscous Kelvin–Helmholtz flows (Yih instability), as well as self-selection of the most unstable wave-number in multimode simulations of Rayleigh–Taylor instability. All these results were obtained with a simple seeding of random infinitesimal disturbances of interface-shape, as opposed to seeding by a complete eigenmode. For other than elementary flows the latter would normally not be available, and extremely difficult to obtain if at all. Sample comparisons with our code adapted to mimic typical diffuse interface treatments were not satisfactory for shear-dominated flows. On the other hand the sharp dynamics of our method would appear to be compatible and possibly advantageous to any interfacial flow algorithm in which the interface is represented as a discrete Heaviside function.</abstract><cop>United States</cop><pub>Elsevier Inc</pub><doi>10.1016/j.jcp.2007.12.008</doi><tpages>31</tpages></addata></record>
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subjects	ALGORITHMS CLASSICAL AND QUANTUM MECHANICS, GENERAL PHYSICS Gas–liquid interfaces HELMHOLTZ INSTABILITY Instability-seeding in numerical simulations Interfacial flows Interfacial instability INTERPOLATION LEAST SQUARE FIT RANDOMNESS RAYLEIGH-TAYLOR INSTABILITY Sharp-interface treatment SIMULATION SURFACE FORCES Viscous Kelvin–Helmholtz instability Yih instability
title	Numerical prediction of interfacial instabilities: Sharp interface method (SIM)
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