Charged fluids encircling compact objects: force representations and conformal geometries

Abstract: Charged fluids rotating around compact objects can form unique equilibrium structures when ambient large-scale electromagnetic fields combine with strong gravity. Equatorial as well as off-equatorial toroidal structures are among such figures of equilibrium with a direct relevance for astrophysics. To investigate their geometrical shapes and physical properties in the near-horizon regime, where effects of general relativity play a significant role, we commonly employ a scheme based on the energy-momentum conse… Show more

“…Equilibrium configurations of a rotating fluid and the conditions for their stability play an important role in astrophysics [1,2]. Previously, we discussed a special case of electrically charged, non-conductive, energetically bound figures of fluid equilibria around black holes [3][4][5][6][7][8][9]. A possibility of (even small) non-vanishing electrical charge greatly enlarges the parameter space of the system.…”

Charged fluid structures around a rotating compact object with a magnetic dipole field

“…Equilibrium configurations of a rotating fluid and the conditions for their stability play an important role in astrophysics [1,2]. Previously, we discussed a special case of electrically charged, non-conductive, energetically bound figures of fluid equilibria around black holes [3][4][5][6][7][8][9]. A possibility of (even small) non-vanishing electrical charge greatly enlarges the parameter space of the system.…”

Charged fluid structures around a rotating compact object with a magnetic dipole field

Charged fluid nonconducting toroidal structures orbiting a Schwarzschild black hole immersed in a split-monopole magnetic field

Stability of rotating, charged fluids: Generalization of the Høiland conditions in Newtonian nonconductive case