1. Dispersion relation for the linear theory of relativistic Rayleigh Taylor instability in magnetized medium revisited
- Author
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Jiang, Qiqi, Li, Guang-Xing, and Singh, Chandra B.
- Subjects
Astrophysics - High Energy Astrophysical Phenomena ,Physics - Fluid Dynamics - Abstract
The Rayleigh Taylor instability (RTI) occurs at the interface between two fluids of different densities, notably when a heavier fluid sits above a lighter one in an effective gravitational field. This instability is relevant to many astrophysical systems where relativistic effects are significant. We examine the linear theory of relativistic Rayleigh Taylor instability (RRTI) in a magnetized medium, allowing for relativistic fluid motion parallel to the interface. To simplify our derivations, we use an "intermediate frame" where fluids on both sides have the same Lorentz factor. Our analysis yields the dispersion relation for RRTI. We find that the instability occurs when the Atwood number $\mathcal{A}$ = $(\rho_1 h_1 - \rho_2 h_2) / (\rho_1 h_1 + \rho_2 h_2) >0$, without requiring relativistic correction. Relativistic motion increases the effective inertia ($\rho \rightarrow \gamma_*^2 \rho$), weakening the magnetic field's suppression of the instability. In the laboratory frame, the instability growth rate is reduced due to time dilation. These analytical results may inform studies of instabilities in systems such as microquasars, active galactic nuclei, gamma-ray bursts, and radio pulsars.
- Published
- 2024