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Autores principales: Chu, Tianyi, Wilfong, Benjamin, Koehler, Timothy, McMullen, Ryan M., Bryngelson, Spencer H.
Formato: Preprint
Publicado: 2025
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Acceso en línea:https://arxiv.org/abs/2505.23578
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author Chu, Tianyi
Wilfong, Benjamin
Koehler, Timothy
McMullen, Ryan M.
Bryngelson, Spencer H.
author_facet Chu, Tianyi
Wilfong, Benjamin
Koehler, Timothy
McMullen, Ryan M.
Bryngelson, Spencer H.
contents Fluid--fluid interfacial instability and subsequent fluid mixing are ubiquitous in nature and engineering. The hydrodynamic instability of fluid interfaces has long centered on the pressure gradient-driven long-wavelength Rayleigh--Taylor instability and the resonance-induced short-wavelength Faraday instability. However, neither instability alone can explain the dynamics when both mechanisms are present. We identify a previously unseen multi-modal instability emerging from their coexistence. When the denser fluid is polydimethylsiloxane, the mixed region at a high density contrast (Atwood number=0.9) spans a vibration amplitude range approximately twice the gravitational acceleration. Using Floquet stability analysis, we show how vibrations govern transitions between the RT and Faraday instabilities, leading to contention between these instabilities rather than resonant enhancement. The initial transient growth is represented by the exponential modal growth of the most unstable Floquet exponent, along with its accompanying periodic behavior. Direct numerical simulations validate these findings and track interface breakup into the multiscale and nonlinear regimes. Specifically, we show that growing RT modes nonlinearly suppress Faraday responses even when the initial growth rate of the Faraday instability is 3.63 times that of RT, so a bidirectional competition hinders their sustained coexistence.
format Preprint
id arxiv_https___arxiv_org_abs_2505_23578
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Competing Mechanisms at Vibrated Interfaces of Density-Contrast Fluids
Chu, Tianyi
Wilfong, Benjamin
Koehler, Timothy
McMullen, Ryan M.
Bryngelson, Spencer H.
Fluid Dynamics
Fluid--fluid interfacial instability and subsequent fluid mixing are ubiquitous in nature and engineering. The hydrodynamic instability of fluid interfaces has long centered on the pressure gradient-driven long-wavelength Rayleigh--Taylor instability and the resonance-induced short-wavelength Faraday instability. However, neither instability alone can explain the dynamics when both mechanisms are present. We identify a previously unseen multi-modal instability emerging from their coexistence. When the denser fluid is polydimethylsiloxane, the mixed region at a high density contrast (Atwood number=0.9) spans a vibration amplitude range approximately twice the gravitational acceleration. Using Floquet stability analysis, we show how vibrations govern transitions between the RT and Faraday instabilities, leading to contention between these instabilities rather than resonant enhancement. The initial transient growth is represented by the exponential modal growth of the most unstable Floquet exponent, along with its accompanying periodic behavior. Direct numerical simulations validate these findings and track interface breakup into the multiscale and nonlinear regimes. Specifically, we show that growing RT modes nonlinearly suppress Faraday responses even when the initial growth rate of the Faraday instability is 3.63 times that of RT, so a bidirectional competition hinders their sustained coexistence.
title Competing Mechanisms at Vibrated Interfaces of Density-Contrast Fluids
topic Fluid Dynamics
url https://arxiv.org/abs/2505.23578